An extra nucleotide in the consensus catalytic core of a viroid hammerhead ribozyme: implications for the design of more efficient ribozymes.

Hammerhead ribozymes catalyze self-cleavage of oligomeric RNAs generated in replication of certain viroid and viroid-like RNAs. Previous studies have defined a catalytic core conserved in most natural hammerheads, but it is still unknown why some present deviations from the consensus. We have addressed this issue in chrysanthemum chlorotic mottle viroid (CChMVd), whose (+) hammerhead has an extra A (A10) between the conserved A9 and the quasi-conserved G10.1. Effects of insertions at this position on hammerhead kinetics have not hitherto been examined. A10 caused a moderate decrease of the trans-cleaving rate constant with respect to the CChMVd (+) hammerhead without this residue, whereas A10-->C and A10-->G substitutions had major detrimental effects, likely because they favor catalytically inactive foldings. By contrast, A10-->U substitution induced a 3-4-fold increase of the rate constant, providing an explanation for the extra U10 present in two natural hammerheads. Because A10 also occupies a singular and indispensable position in the global CChMVd conformation, as revealed by bioassays, these results show that some hammerheads deviate from the consensus due to the involvement of certain residues in critical function(s) other than self-cleavage. Incorporation of the extra U10 into a model hammerhead also caused a similar increase in the rate constant, providing data for a deeper understanding of the hammerhead structural requirements and for designing more efficient ribozymes.     

Peripheral regions of natural hammerhead ribozymes greatly increase their self-cleavage activity

Natural hammerhead ribozymes are mostly found in some viroid and viroid-like RNAs and catalyze their cis cleavage during replication. Hammerheads have been manipulated to act in trans and assumed to have a similar catalytic behavior in this artificial context. However, we show here that two natural cis-acting hammerheads self-cleave much faster than trans-acting derivatives and other reported artificial hammerheads. Moreover, modifications of the peripheral loops 1 and 2 of one of these natural hammerheads induced a >100-fold reduction of the self-cleavage constant, whereas engineering a trans-acting artificial hammerhead into a cis derivative by introducing a loop 1 had no effect. These data show that regions external to the central conserved core of natural hammerheads play a role in catalysis, and suggest the existence of tertiary interactions between these peripheral regions. The interactions, determined by the sequence and size of loops 1 and 2 and most likely of helices I and II, must result from natural selection and should be studied in order to better understand the hammerhead requirements in vivo.     

Alternative tertiary structure attenuates self-cleavage of the ribozyme in the satellite RNA of barley yellow dwarf virus.

A self-cleaving satellite RNA associated with barley yellow dwarf virus (sBYDV) contains a sequence predicted to form a secondary structure similar to catalytic RNA molecules (ribozymes) of the 'hammerhead' class (Miller et al., 1991, Virology 183, 711-720). However, this RNA differs from other naturally occurring hammerheads both in its very slow cleavage rate, and in some aspects of its structure. One striking structural difference is that an additional helix is predicted that may be part of an unusual pseudoknot containing three stacked helices. Nucleotide substitutions that prevent formation of the additional helix and favor the hammerhead increased the self-cleavage rate up to 400-fold. Compensatory substitutions, predicted to restore the additional helix, reduced the self-cleavage rate by an extent proportional to the calculated stability of the helix. Partial digestion of the RNA with structure-sensitive nucleases supported the existence of the proposed alternative structure in the wildtype sequence, and formation of the hammerhead in the rapidly-cleaving mutants. This tertiary interaction may serve as a molecular switch that controls the rate of self-cleavage and possibly other functions of the satellite RNA.     

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.     

Eggplant latent viroid,the candidate type species for a new genus within the family Avsunviroidae (hammerhead viroids)

Viroids, small circular RNAs that replicate independently and in most cases incite diseases in plants, are classified into the families Pospiviroidae, composed of species with a central conserved region (CCR) and without hammerhead ribozymes, and Avsunviroidae, composed of three members lacking CCR but able to self-cleave in both polarity strands through hammerhead ribozymes. Here we report the biological and molecular properties of Eggplant latent viroid (ELVd). Purified circular ELVd induces symptomless infections when inoculated into eggplant seedlings. ELVd can be transmitted horizontally and through seed. Sequencing 10 complete cDNA clones showed that ELVd is a circular RNA of 332 to 335 nucleotides with high variability. This RNA can adopt a quasi-rod-like secondary structure of minimal free energy and alternative foldings that permit formation of stable hammerhead structures in plus and minus strands. The ribozymes are active in vitro and, most likely, in vivo. Considering the ELVd properties to be intermediate between those of the two genera of family Avsunviroidae, we propose ELVd as the type species of a third genus with the name ELAVIROID:     

Satellite cereal yellow dwarf virus-RPV (satRPV) RNA requires a douXble hammerhead for self-cleavage and an alternative structure for replication.

The 110 nt hammerhead ribozyme in the satellite RNA of cereal yellow dwarf virus-RPV (satRPV RNA) folds into an alternative conformation that inhibits self-cleavage. This alternative structure comprises a pseudoknot with base-pairing between loop (L1) and a single-stranded bulge (L2a), which are located in hammerhead stems I and II, respectively. Mutations that disrupt this base-pairing, or otherwise cause the ribozyme to more closely resemble a canonical hammerhead, greatly increase self-cleavage. In a more natural multimeric sequence context containing the full-length satRPV RNA and two copies of the hammerhead, wild-type RNA cleaves much more efficiently than in the 110 nt context. Mutations in the upstream hammerhead, including a knock-out in the catalytic core, affect cleavage at the downstream cleavage site, indicating that multimers of satRPV RNA cleave via a double hammerhead. The double hammerhead includes base-pairing between two copies of the L1 sequence which extends stem I. Disruption of L1-L1 base-pairing slows cleavage of the multimer. L1-L2a base-pairing is required for efficient replication of satRPV RNA in oat protoplasts. Mutations that affect self-cleavage of the multimer do not correlate with replication efficiency, indicating that the ability to self-cleave is not a primary determinant of replication. We present a replication model in which multimeric satRPV RNA folds into alternative conformations that cannot form in the monomer. One potential metastable intermediate conformation involves L1-L2a base-pairing that may facilitate formation of the double hammerhead. However, we conclude that L1-L2a also performs some other essential function in the satRPV RNA replication cycle, because the L1-L2a base-pairing is more important than efficient self-cleavage for replication.     

Structure–function analysis of the ribozymes of chrysanthemum chlorotic mottle viroid: a loop–loop interaction motif conserved in most natural hammerheads

Loop–loop tertiary interactions play a key role in the folding and catalytic activity of natural hammerhead ribozymes. Using a combination of NMR spectroscopy, site-directed mutagenesis and kinetic and infectivity analyses, we have examined the structure and function of loops 1 and 2 of the (+) and (–) hammerheads of chrysanthemum chlorotic mottle viroid RNA. In both hammerheads, loop 1 is a heptanucleotide hairpin loop containing an exposed U at its 5′ side and an extrahelical U at its 3′-side critical for the catalytic activity of the ribozyme in vitro and for viroid infectivity in vivo, whereas loop 2 has a key opened A at its 3′-side. These structural features promote a specific loop–loop interaction motif across the major groove. The essential features of this tertiary structure element, base pairing between the 5′ U of loop 1 and the 3′ A of loop 2, and interaction of the extrahelical pyrimidine of loop 1 with loop 2, are likely shared by a significant fraction of natural hammerheads.     

Catalytic diversity of extended hammerhead ribozymes

Chimeras of the well-characterized minimal hammerhead 16 and nine extended hammerheads derived from natural viroids and satellite RNAs were constructed with the goal of assessing whether their very different peripheral tertiary interactions modulate their catalytic properties. For each chimera, three different assays were used to determine the rate of cleavage and the fraction of full-length hammerhead at equilibrium and thereby deduce the elemental cleavage ( k 2) and ligation ( k -2) rate constants. The nine chimeras were all more active than minimal hammerheads and exhibited a very broad range of catalytic properties, with values of k 2 varying by 750-fold and k -2 by 100-fold. At least two of the hammerheads exhibited an altered dependence of k obs on magnesium concentration. Since much less catalytic diversity is observed among minimal hammerheads that lack the tertiary interactions, a possible role for the different tertiary interaction is to modulate the hammerhead cleavage properties in viroids. For example, differing hammerhead cleavage and ligation rates could affect the steady state concentrations of linear, circular, and polymeric genomes in infected cells.     

The biology and conservation status of the large hammerhead shark complex: the great,scalloped, and smooth hammerheads

Hammerhead sharks are among the most intriguing yet imperiled groups of large sharks globally. Until recently, our understanding of their biology, movements, diet, and life histories was challenged by a lack of studies. In recent years there has been a surge of published studies on this group of sharks, incorporating new information on age and growth, behavior, and the threats they face. Here we summarize and compare what is known on the biology and conservation of the three largest species of hammerhead sharks: the great hammerhead (Sphyrna mokarran), the scalloped hammerhead (Sphyrna lewini), and the smooth hammerhead (Sphyrna zygaena). We chose these species since they are the most well-studied of the hammerheads, and also because they are commonly captured in target and non-target fisheries worldwide. Thus, we also discuss population trends and the vulnerabilities of each species, and make recommendations for future studies on these fascinating and complex elasmobranch fishes.     

Three conserved guanosines approach the reaction site in native and minimal hammerhead ribozymes

Native hammerhead ribozymes contain RNA domains that enable high catalytic activity under physiological conditions, where minimal hammerheads show little activity. However, little is known about potential differences in native versus minimal ribozyme folding. Here, we present results of photocross-linking analysis of native and minimal hammerheads containing photoreactive nucleobases 6-thioguanosine, 2,6-diaminopurine, 4-thiouridine, and pyrrolocytidine, introduced at specific sites within the catalytic core. Under conditions where catalytic activity is observed, the two substrate nucleobases spanning the cleavage site approach and stack upon G8 and G12 of the native hammerhead, two conserved nucleobases that show similar behavior in minimal constructs, have been implicated in general acid-base catalysis, and are >15 A from the cleavage site in the crystal structures. Pyrrolocytidine at cleavage site position 17 forms an efficient crosslink to G12, and the crosslinked RNA retains catalytic activity. Multiple cross-linked species point to a structural rearrangement within the U-turn, positioning residue G5 in the vicinity of cleavage site position 1.1. Intriguing crosslinks were triggered by nucleotide analogues at positions distal to the crosslinked residues; for example, 6-thioguanosine at position 5 induced a crosslink between G12 and C17, suggesting an intimate functional communication among these three nucleobases. Together, these results support a model in which the native hammerhead folds to an active structure similar to that of the minimal ribozyme, and significantly different from the crystallographic structures.     

Inosine(15.1) hammerhead ribozymes for targeting the transthyretin-30 mutation.

The most common cause of hereditary amyloidosis (HA) is the val30met mutation in the transthyretin protein (TTR-met30). The mutation is caused by a mononucleic substitution from G to A (GUC to AUC) in the transthyretin gene resulting in the exchange for the amino acids valine to methionine in the corresponding protein sequence. The aim of our work was the development of a specific cleavage of TTR-30 mRNA using hammerhead ribozymes. We chemically modified nuclease stable hammerhead ribozymes to target the TTR-30 mRNA with high specificity. The exchange of adenosine(15.1) with inosine(15.1) in the catalytic core of the hammerhead ribozyme resulted in a change of the cleavable target sequence from N(16.2)U(16.1)H(17) to N(16. 2)C(16.1)H(17) without loss in ribozymal activity (Nucleic Acids Res. 26, 2279-2285, 1998). This modification allowed a specific cleavage of the TTR-30 mutation ("gCC Gug" to "gCC Aug"). In vitro experiments with TTR-30 mRNA demonstrated that the RNase stable inosine(15.1) hammerhead ribozyme cleaved the TTR-30 mRNA with 100% specificity and with a velocity of 0.23 min(-1), whereas no cleavage occured in the wildtype mRNA of TTR. In conclusion, the development of this NCH specific hammerhead ribozyme represents a promising tool for future in vivo therapeutic application for TTR-met30 induced hereditary amyloidosis.     

A sequence element necessary for self-cleavage of the antigenomic hepatitis delta RNA in 20 M formamide.

The genomic and antigenomic RNAs of hepatitis delta virus are capable of self-cleavage and show no significant sequence similarities to other known self-cleaving RNAs. We have derived an antigenomic delta RNA which cleaves to completion in 15 s in 9 mM magnesium at 37 degrees C and is capable of efficient self-cleavage in concentrations of formamide as high as 20 M. Cleavage in high concentrations of denaturant is dependent upon the presence of a polypurine sequence element, GGAGA, located between 81 and 85 nucleotides downstream of the cleavage site. Mutation of the initial G81G82 to C81C82, or removal of the sequence element, results in a loss of the ability to cleave in high formamide concentrations. Changing the final U-2C-1 of a pyrimidine-rich region, UCUUC, just upstream of the cleavage site, to G-2G-1 severely affects the self-cleavage, but introducing the two mutations, GG to CC and UC to GG, into the same molecule, restoring potential base pairing, partially restores the formamide stability. Relocating the GGAGA sequence upstream of the cleavage site also results in partial restoration of the formamide cleavage. Although the GGAGA sequence is important for self-cleavage under denaturing conditions, it does not appear to be necessary for HDV RNA cleavage in normal buffer conditions.     

Hammerheads derived from sTRSV show enhanced cleavage and ligation rate constants

The catalytic properties of the hammerhead ribozyme embedded in the (+) strand of the satellite tobacco ringspot viral genome are analyzed with the goal of obtaining the elemental rate constants of the cleavage (k(2)) and ligation (k(-)(2)) steps. Two different chimeras combining the sTRSV (+) hammerhead and the well-characterized hammerhead 16 were used to measure the cleavage rate constant (k(2)), the rate of approach to equilibrium (k(obs) = k(2) + k(-)(2)), and the fraction of full-length hammerhead at equilibrium (k(-)(2)/k(2) + k(-)(2)). When compared to minimal hammerheads that lack the recently discovered loop I-loop II interaction, an extended format hammerhead derived from sTRSV studied here shows at least a 20-fold faster k(2) and a 1300-fold faster k(-)(2) at 10 mM MgCl(2). However, the magnesium dependence of the cleavage rate is not significantly changed. Thus, the enhanced cleavage of this hammerhead observed in vivo is due to its higher intrinsic rate and not due to its tighter binding of magnesium ions. The faster k(-)(2) of this hammerhead suggests that ligation may be used to form circular RNA genomes. This in vitro system will be valuable for experiments directed at understanding the hammerhead mechanism and the role of the loop I-loop II interaction.     

Probing the hammerhead ribozyme structure with ribonucleases.

Susceptibility to RNase digestion has been used to probe the conformation of the hammerhead ribozyme structure prepared from chemically synthesised RNAs. Less than about 1.5% of the total sample was digested to obtain a profile of RNase digestion sites. The observed digestion profiles confirmed the predicted base-paired secondary structure for the hammerhead. Digestion profiles of both cis and trans hammerhead structures were nearly identical which indicated that the structural interactions leading to self-cleavage were similar for both systems. Furthermore, the presence or absence of Mg2+ did not affect the RNase digestion profiles, thus indicating that Mg2+ did not modify the hammerhead structure significantly to induce self-cleavage. The base-paired stems I and II in the hammerhead structure were stable whereas stem III, which was susceptible to digestion, appeared to be an unstable region. The single strand domains separating the stems were susceptible to digestion with the exception of sites adjacent to guanosines; GL2.1 in the stem II loop and G12 in the conserved GAAAC sequence, which separates stems II and III. The absence of digestion at GL2.1 in the stem II hairpin loop of the hammerhead complex was maintained in uncomplexed ribozyme and in short oligonucleotides containing only the stem II hairpin region. In contrast, the G12 site became susceptible when the ribozyme was not complexed with its substrate. Overall the results are consistent with the role of Mg2+ in the hammerhead self-cleavage reaction being catalytic and not structural.