Ion-induced folding of the hammerhead ribozyme: a fluorescence resonance energy transfer study.

The ion-induced folding transitions of the hammerhead ribozyme have been analysed by fluorescence resonance energy transfer. The hammerhead ribozyme may be regarded as a special example of a three-way RNA junction, the global structure of which has been studied by comparing the distances (as energy transfer efficiencies) between the ends of pairs of labelled arms for the three possible end-to-end vectors as a function of magnesium ion concentration. The data support two sequential ion-dependent transitions, which can be interpreted in the light of the crystal structures of the hammerhead ribozyme. The first transition corresponds to the formation of a coaxial stacking between helices II and III; the data can be fully explained by a model in which the transition is induced by a single magnesium ion which binds with an apparent association constant of 8000-10 000 M-1. The second structural transition corresponds to the formation of the catalytic domain of the ribozyme, induced by a single magnesium ion with an apparent association constant of approximately 1100 M-1. The hammerhead ribozyme provides a well-defined example of ion-dependent folding in RNA.     

Effects of variations in length of hammerhead ribozyme antisense arms upon the cleavage of longer RNA substrates.

The efficacy of intracellular binding of hammerhead ribozyme to its cleavage site in target RNA is a major requirement for its use as a therapeutic agent. Such efficacy can be influenced by several factors, such as the length of the ribozyme antisense arms and mRNA secondary structures. Analysis of various IL-2 hammerhead ribozymes having different antisense arms but directed to the same site predicts that the hammerhead ribozyme target site is present within a double-stranded region that is flanked by single-stranded loops. Extension of the low cleaving hammerhead ribozyme antisense arms by nucleotides that base pair with the single-stranded regions facilitated the hammerhead ribozyme binding to longer RNA substrates (e.g. mRNA). In addition, a correlation between the in vitro and intracellular results was also found. Thus, the present study would facilitate the design of hammerhead ribozymes directed against higher order structured sites. Further, it emphasises the importance of detailed structural investigations of hammerhead ribozyme full-length target RNAs.     

Effects of phosphorothioate and 2-amino groups in hammerhead ribozymes on cleavage rates and Mg2+ binding

Mg2+ is important for the RNase activity of the hammerhead ribozyme. To investigate the binding properties of Mg2+ to the hammerhead ribozyme, cleavage rates and CD spectra for substrates containing inosine or guanosine at the cleavage site were measured. The 2-amino group of this guanosine interfered with the rate of the cleavage reaction and did not affect the amount of Mg2+ bound to the hammerhead RNA. The kinetics and CD spectra for chemically synthesized oligoribonucleotides with a Sp or Rp phosphorothioate diester bond at the cleavage site indicated that 1 mol of Mg2+ binds to the pro-R oxygen of phosphate. The binding constant for Mg2+ was about 10(4) M-1, which represents outer-sphere complexation. The hammerhead ribozyme catalyzes the cleavage reaction via an in-line pathway. This mechanism has been proved for RNA cleavage by RNase A by using a modified oligonucleotide that has an Sp phosphorothionate bond at the cleavage site. From these results, we present the reaction pathway and a model for Mg2+ binding to the hammerhead ribozyme.     

A covalent crosslink converts the hammerhead ribozyme from a ribonuclease to an RNA ligase

The hammerhead ribozyme is a more efficient ribonuclease than an RNA ligase. Under typical reaction conditions, the rate of RNA chain cleavage is approximately 100-fold faster than the rate of the reverse ligation reaction such that virtually all of the hammerhead is in its cleaved form at equilibrium. Here we show that the introduction of a crosslink away from the catalytic core of the hammerhead has little effect on the cleavage rate but dramatically increases the ligation rate, thereby making the hammerhead an efficient RNA ligase. This experiment emphasizes the role of molecular flexibility in defining the properties of a macromolecular catalyst and suggests why other small ribozymes are more efficient ligases than ribonucleases.     

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.     

Structure—function studies of the hammerhead ribozyme

Elucidation of the catalytic mechanism and structure—function relationship studies of the hammerhead ribozyme continue to be an area of intensive research. A combination of diverse approaches, such as X ray crystallography, spectral studies, chemical modifications, sequence variations and kinetic analyses, have provided valuable insight into the cleavage mechanism of this ribozyme. The hammerhead ribozyme crystal structures have provided valuable insight into conformational deformations needed to attain the catalytically active structure. Similarly, determination of ribozyme solution structure by spectroscopic analyses and the effect of divalent metal ions on RNA folding has further aided in the construction of a model for hammerhmead catalysis.     

Characterization in vitro and in vivo of hammerhead ribozymes directed against murine tumor necrosis factoralpha.

A hammerhead ribozyme directed against murine TNFalpha (mTNFalpha) mRNA has been constructed. In vitro studies showed that this ribozyme was released from the parent molecule by flanking cis-acting hammerhead and hairpin ribozymes. This same anti-mTNFalpha ribozyme specifically cleaved both synthetically derived substrate RNA and mTNFalpha mRNA within a pool of total cellular RNA. Endogenous delivery of this anti-mTNFalpha ribozyme via the self-cleaving cassette reduced mTNFalpha mRNA and protein levels in lipopolysaccharide (LPS)-stimulated, stably transfected murine macrophage RAW 264.7 cells. When complexed to liposomes and exogenously delivered to mouse peritoneal macrophages, the same ribozyme, with and without the cis-acting ribozymes, reduced mTNFalpha protein levels. However, an irrelevant ribozyme delivered in an identical fashion was also effective at reducing mTNFalpha protein levels. These data suggest that anti-mTNFalpha ribozymes can be constructed which efficiently cleave mTNFalpha mRNA, but irrelevant RNA/liposome complexes also effectively limit TNFalpha mRNA expression and can mimic functional ribozyme activity under in vitro conditions.     

Molecular dynamics investigations of hammerhead ribozyme RNA

The hammerhead ribozyme, a small catalytic RNA molecule, cleaves, in the presence of magnesium ions, a specific phosphodiester bond within its own backbone, leading to 23-cyclic phosphate and 5-OH extremities. In order to study the dynamical flexibility of the hammerhead RNA, we performed molecular dynamics simulations of the solvated crystal structure of an active hammerhead ribozyme, obtained after flash-freezing crystals soaked with magnesium. Because of a careful equilibration protocol and the use of the Ewald summation in calculating the electrostatic interactions, the RNA structure remained close to the crystal structure, as attested by a root-mean-square deviation below 2.5 A after 750 ps of simulation. All Watson-Crick base pairs were intact at the end of the simulations. The tertiary interactions, such as the sheared G.A pairs and the U-turn, important for the stabilisation of the three-dimensional RNA fold, were also retained. The results demonstrate that molecular dynamics simulations can be successfully used to investigate the dynamical behaviour of a ribozyme, thus, opening a road to study the role of transient structural changes involved in ribozyme catalysis.     

Inhibition of hepatitis B virus by hammerhead ribozyme targeted to the poly(A) signal sequence in cultured cells

The deviant poly(A) signal of hepatitis B virus (HBV) not only controls the formation of the 3' end of all the viral RNA, but is also crucial for HBV replication. Hence, a cis-releasing hammerhead ribozyme (RzA) targeted to the poly(A) signal region of HBV subtype adr was investigated for its antiviral effects. In vitro, RzA cleaved HBV RNA at its target site up to 70%, while the disabled ribozyme (dRzA), which had a one-base mutation in the catalytic site, did not cleave the target RNA at all. When the ribozymes were cotransfected into HepG2 cells with the HBV genome-containing plasmid p3.6II, the wild-type ribozyme RzA could effectively decrease HBV RNA levels and inhibit HBV replication, whereas its disabled form, dRzA, had much weaker effects, indicating that the active catalytic domain of the hammerhead ribozyme could markedly increase the extent of antisense-mediated inhibition. In addition, there was a gradient of effectiveness: the higher the amount of released ribozyme, the more the reduction in target HBV RNA in cells as well as progeny DNA reduction. These results suggest the possibility of the hammerhead ribozyme RzA to be used for the gene therapy of HBV infection.     

The ubiquitous hammerhead ribozyme

The hammerhead ribozyme is a small catalytic RNA motif capable of endonucleolytic (self-) cleavage. It is composed of a catalytic core of conserved nucleotides flanked by three helices, two of which form essential tertiary interactions for fast self-scission under physiological conditions. Originally discovered in subviral plant pathogens, its presence in several eukaryotic genomes has been reported since. More recently, this catalytic RNA motif has been shown to reside in a large number of genomes. We review the different approaches in discovering these new hammerhead ribozyme sequences and discuss possible biological functions of the genomic motifs.     

Identification and characterization of a novel high affinity metal-binding site in the hammerhead ribozyme.

A novel metal-binding site has been identified in the hammerhead ribozyme by 31P NMR. The metal-binding site is associated with the A13 phosphate in the catalytic core of the hammerhead ribozyme and is distinct from any previously identified metal-binding sites. 31P NMR spectroscopy was used to measure the metal-binding affinity for this site and leads to an apparent dissociation constant of 250-570 microM at 25 degrees C for binding of a single Mg2+ ion. The NMR data also show evidence of a structural change at this site upon metal binding and these results are compared with previous data on metal-induced structural changes in the core of the hammerhead ribozyme. These NMR data were combined with the X-ray structure of the hammerhead ribozyme (Pley HW, Flaherty KM, McKay DB. 1994. Nature 372:68-74) to model RNA ligands involved in binding the metal at this A13 site. In this model, the A13 metal-binding site is structurally similar to the previously identified A(g) metal-binding site and illustrates the symmetrical nature of the tandem G x A base pairs in domain 2 of the hammerhead ribozyme. These results demonstrate that 31P NMR represents an important method for both identification and characterization of metal-binding sites in nucleic acids.     

HIV-1 TAR as anchoring site for optimized catalytic RNAs

Ribozymes have a great potential for developing specific gene silencing molecules. One of the main limitations to ensure the efficient application of ribozymes is to achieve effective binding to the target. Stem-loop domains support efficient formation of the kissing complex between natural antisense molecules and their target sequence. We have characterized catalytic antisense RNA hybrid molecules composed of a hammerhead ribozyme and a stem-loop antisense domain. A series of artificial RNA substrates containing the TAR-RNA stem-loop and a target for the hammerhead ribozyme were constructed and challenged with a catalytic antisense RNA carrying the TAR complementary stem-loop. The catalytic antisense RNA cleaves each of these substrates significantly more efficiently than the parental hammerhead ribozyme. Deletion of the TAR domain in the substrate abolishes the positive effect. These results suggest that the enhancement is due to the interaction of both complementary stem-loop motifs. A similar improvement was corroborated when targeting the LTR region of HIV-1 with either hammerhead- and hairpin-based catalytic antisense RNAs. Our results indicate that the TAR domain can be used as an anchoring site to facilitate the access of ribozymes to their specific target sequences within TAR-containing RNAs. Finally, we propose the addition of stable stem-loop motifs to the ribozyme domain as a rational way for constructing catalytic antisense RNAs.     

Generation and application of asymmetric hammerhead ribozymes.

Most researchers who intend to suppress a particular gene are interested primarily in the application of ribozyme technology rather than its mechanistic details. This article provides some background information and describes a straightforward strategy to generate and test a special design of a ribozyme: the asymmetric hammerhead ribozyme. This version of a hammerhead ribozyme carries at its 5' end the catalytic domain and at its 3' end a relatively long antisense flank that is complementary to the target RNA. Asymmetric hammerhead ribozymes can be constructed via polymerase chain reaction amplification, and rules are provided on how to select the DNA oligonucleotides required for this reaction. In addition to details on construction, we describe how to test asymmetric hammerhead ribozymes for association with the target RNA in vitro, so that RNA constructs can be selected and optimized for fast hybridization with their target RNA. This test can allow one to minimize association problems caused by the secondary structure of the target RNA. Additionally, we describe the in vitro cleavage assay and the determination of the cleavage rate constant. Testing for efficient cleavage is also a prerequisite for reliable and successful application of the technology. A carefully selected RNA will be more promising when eventually used for target suppression in living cells.     

Structure and function of regulatory RNA elements: Ribozymes that regulate gene expression

Since their discovery in the 1980s, it has gradually become apparent that there are several functional classes of naturally occurring ribozymes. These include ribozymes that mediate RNA splicing (the Group I and Group II introns, and possibly the RNA components of the spliceosome), RNA processing ribozymes (RNase P, which cleaves precursor tRNAs and other structural RNA precursors), the peptidyl transferase center of the ribosome, and small, self-cleaving genomic ribozymes (including the hammerhead, hairpin, HDV and VS ribozymes). The most recently discovered functional class of ribozymes include those that are embedded in the untranslated regions of mature mRNAs that regulate the gene's translational expression. These include the prokaryotic glmS ribozyme, a bacterial riboswitch, and a variant of the hammerhead ribozyme, which has been found embedded in mammalian mRNAs. With the discovery of a mammalian riboswitch ribozyme, the question of how an embedded hammerhead ribozyme's switching mechanism works becomes a compelling question. Recent structural results suggest several possibilities.     

Sequence requirements of the hammerhead RNA self-cleavage reaction.

A previously well-characterized hammerhead catalytic RNA consisting of a 24-nucleotide substrate and a 19-nucleotide ribozyme was used to perform an extensive mutagenesis study. The cleavage rates of 21 different substrate mutations and 24 different ribozyme mutations were determined. Only one of the three phylogenetically conserved base pairs but all nine of the conserved single-stranded residues in the central core are needed for self cleavage. In most cases the mutations did not alter the ability of the hammerhead to assemble into a bimolecular complex. In the few cases where mutant hammerheads did not assemble, it appeared to be the result of the mutation stabilizing an alternate substrate or ribozyme secondary structure. All combinations of mutant substrate and mutant ribozyme were less active than the corresponding single mutations, suggesting that the hammerhead contains few, if any, replaceable tertiary interactions as are found in tRNA. The refined consensus hammerhead resulting from this work was used to identify potential hammerheads present in a variety of Escherichia coli gene sequences.     

Structure and function of the hairpin ribozyme

The hairpin ribozyme belongs to the family of small catalytic RNAs that cleave RNA substrates in a reversible reaction that generates 2',3'-cyclic phosphate and 5'-hydroxyl termini. The hairpin catalytic motif was discovered in the negative strand of the tobacco ringspot virus satellite RNA, where hairpin ribozyme-mediated self-cleavage and ligation reactions participate in processing RNA replication intermediates. The self-cleaving hairpin, hammerhead, hepatitis delta and Neurospora VS RNAs each adopt unique structures and exploit distinct kinetic and catalytic mechanisms despite catalyzing the same chemical reactions. Mechanistic studies of hairpin ribozyme reactions provided early evidence that, like protein enzymes, RNA enzymes are able to exploit a variety of catalytic strategies. In contrast to the hammerhead and Tetrahymena ribozyme reactions, hairpin-mediated cleavage and ligation proceed through a catalytic mechanism that does not require direct coordination of metal cations to phosphate or water oxygens. The hairpin ribozyme is a better ligase than it is a nuclease while the hammerhead reaction favors cleavage over ligation of bound products by nearly 200-fold. Recent structure-function studies have begun to yield insights into the molecular bases of these unique features of the hairpin ribozyme.