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.     

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.     

Long-range tertiary interactions in single hammerhead ribozymes bias motional sampling toward catalytically active conformations

Enzymes generally are thought to derive their functional activity from conformational motions. The limited chemical variation in RNA suggests that such structural dynamics may play a particularly important role in RNA function. Minimal hammerhead ribozymes are known to cleave efficiently only in ～ 10-fold higher than physiologic concentrations of Mg(2+) ions. Extended versions containing native loop-loop interactions, however, show greatly enhanced catalytic activity at physiologically relevant Mg(2+) concentrations, for reasons that are still ill-understood. Here, we use Mg(2+) titrations, activity assays, ensemble, and single molecule fluorescence resonance energy transfer (FRET) approaches, combined with molecular dynamics (MD) simulations, to ask what influence the spatially distant tertiary loop-loop interactions of an extended hammerhead ribozyme have on its structural dynamics. By comparing hammerhead variants with wild-type, partially disrupted, and fully disrupted loop-loop interaction sequences we find that the tertiary interactions lead to a dynamic motional sampling that increasingly populates catalytically active conformations. At the global level the wild-type tertiary interactions lead to more frequent, if transient, encounters of the loop-carrying stems, whereas at the local level they lead to an enrichment in favorable in-line attack angles at the cleavage site. These results invoke a linkage between RNA structural dynamics and function and suggest that loop-loop interactions in extended hammerhead ribozymes-and Mg(2+) ions that bind to minimal ribozymes-may generally allow more frequent access to a catalytically relevant conformation(s), rather than simply locking the ribozyme into a single active state.     

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.     

Efficient ligation of the Schistosoma hammerhead ribozyme

The hammerhead ribozyme from Schistosoma mansoni is the best characterized of the natural hammerhead ribozymes. Biophysical, biochemical, and structural studies have shown that the formation of the loop-loop tertiary interaction between stems I and II alters the global folding, cleavage kinetics, and conformation of the catalytic core of this hammerhead, leading to a ribozyme that is readily cleaved under physiological conditions. This study investigates the ligation kinetics and the internal equilibrium between cleavage and ligation for the Schistosoma hammerhead. Single turnover kinetic studies on a construct where the ribozyme cleaves and ligates substrate(s) in trans showed up to 23% ligation when starting from fully cleaved products. This was achieved by an approximately 2000-fold increase in the rate of ligation compared to a minimal hammerhead without the loop-loop tertiary interaction, yielding an internal equilibrium that ranges from 2 to 3 at physiological Mg2+ ion concentrations (0.1-1 mM). Thus, the natural Schistosoma hammerhead ribozyme is almost as efficient at ligation as it is at cleavage. The results here are consistent with a model where formation of the loop-loop tertiary interaction leads to a higher population of catalytically active molecules and where formation of this tertiary interaction has a much larger effect on the ligation than the cleavage activity of the Schistosoma hammerhead ribozyme.     

Kinetic characterization of two I/II format hammerhead ribozymes.

Five new hammerhead ribozymes were designed that assemble through the formation of helices I and II (I/II format) instead of the more standard assembly through helices I and III (I/III format). The substrate binding and cleavage properties of such hammerheads could potentially be different due to the absence of loop II and the requirement for the entire catalytic core to assemble. Two I/II format hammerheads, HHalpha1 and HHalpha5, which show structural homogeneity on native gels, were characterized kinetically. The association rate constants of both I/II hammerheads are unusually slow compared to the rate of RNA duplex formation. The dissociation rate constants indicate that the hammerhead core destabilizes an uninterrupted RNA helix somewhat less than was observed for I/III hammerheads. Whereas the cleavage rate constant of HHalpha5 is similar to that observed for I/III hammerheads, HHalpha1 cleaves 10-fold faster than any hammerhead previously reported. The temperature and pH dependence of the cleavage rate constant of HHalpha1 are similar to those reported for I/III hammerheads, suggesting a similar mechanism of cleavage.     

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.     

Metal-phosphate interactions in the hammerhead ribozyme observed by 31P NMR and phosphorothioate substitutions

The hammerhead ribozyme is a catalytic RNA that requires divalent metal cations for activity under moderate ionic strength. Two important sites that are proposed to bind metal ions in the hammerhead ribozyme are the A9/G10.1 site, located at the junction between stem II and the conserved core, and the scissile phosphate (P1.1). (31)P NMR spectroscopy in conjunction with phosphorothioate substitutions is used in this study to investigate these putative metal sites. The (31)P NMR feature of a phosphorothioate appears in a unique spectral window and can be monitored for changes upon addition of metals. Addition of 1-2 equiv of Cd(2+) to the hammerhead with an A9-S(Rp) or A9-S(S)(Rp) substitution results in a 2-3 ppm upfield shift of the (31)P NMR resonance. In contrast, the P1.1-S(Rp) and P1.1-S(Sp) (31)P NMR features shift slightly and in opposite directions, with a total change in delta of 相似文献   

Minimal and extended hammerheads utilize a similar dynamic reaction mechanism for catalysis

Analysis of the catalytic activity of identical mutations in the catalytic cores of nHH8, a very active "extended" hammerhead, and HH16, a less active "minimal" hammerhead, reveal that the tertiary Watson-Crick base pair between C3 and G8 seen in the recent structure of the Schistosoma mansoni extended hammerhead can be replaced by other base pairs in both backgrounds. This supports the model that both hammerheads utilize a similar catalytic mechanism but HH16 is slower because it infrequently samples the active conformation. The relative effect of different mutations at positions 3 and 8 also depends on the identity of residue 17 in both nHH8 and HH16. This synergistic effect can best be explained by transient pairing between residues 3 and 17 and 8 and 13, which stabilize an inactive conformation. Thus, mutants of nHH8 and possibly nHH8 itself are also in dynamic equilibrium with an inactive conformation that may resemble the X-ray structure of a minimal hammerhead. Therefore, both minimal and extended hammerhead structures must be considered to fully understand hammerhead catalysis.     

Identification of the hammerhead ribozyme metal ion binding site responsible for rescue of the deleterious effect of a cleavage site phosphorothioate

The hammerhead ribozyme crystal structure identified a specific metal ion binding site referred to as the P9/G10.1 site. Although this metal ion binding site is approximately 20 A away from the cleavage site, its disruption is highly deleterious for catalysis. Additional published results have suggested that the pro-R(P) oxygen at the cleavage site is coordinated by a metal ion in the reaction's transition state. Herein, we report a study on Cd(2+) rescue of the deleterious phosphorothioate substitution at the cleavage site. Under all conditions, the Cd(2+) concentration dependence can be accounted for by binding of a single rescuing metal ion. The affinity of the rescuing Cd(2+) is sensitive to perturbations at the P9/G10.1 site but not at the cleavage site or other sites in the conserved core. These observations led to a model in which a metal ion bound at the P9/G10.1 site in the ground state acquires an additional interaction with the cleavage site prior to and in the transition state. A titration experiment ruled out the possibility that a second tight-binding metal ion (< 10 microM) is involved in the rescue, further supporting the single metal ion model. Additionally, weakening Cd(2+) binding at the P9/G10.1 site did not result in the biphasic binding curve predicted from other models involving two metal ions. The large stereospecific thio-effects at the P9/G10.1 and the cleavage site suggest that there are interactions with these oxygen atoms in the normal reaction that are compromised by replacement of oxygen with sulfur. The simplest interpretation of the substantial rescue by Cd(2+) is that these atoms interact with a common metal ion in the normal reaction. Furthermore, base deletions and functional group modifications have similar energetic effects on the transition state in the Cd(2+)-rescued phosphorothioate reaction and the wild-type reaction, further supporting the model that a metal ion bridges the P9/G10.1 and the cleavage site in the normal reaction (i.e., with phosphate linkages rather than phosphorothioate linkages). These results suggest that the hammerhead undergoes a substantial conformational rearrangement to attain its catalytic conformation. Such rearrangements appear to be general features of small functional RNAs, presumably reflecting their structural limitations.     

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.     

Sequence elements outside the hammerhead ribozyme catalytic core enable intracellular activity

The hammerhead ribozyme (HHRz) is a small, naturally occurring ribozyme that site-specifically cleaves RNA and has long been considered a potentially useful tool for gene silencing. The minimal conserved HHRz motif derived from natural sequences consists of three helices that intersect at a highly conserved catalytic core of 11 nucleotides. The presence of this motif is sufficient to support cleavage at high Mg2+ concentrations, but not at the low Mg2+ concentrations characteristic of intracellular environments. Here we demonstrate that natural HHRzs require the presence of additional nonconserved sequence elements outside of the conserved catalytic core to enable intracellular activity. These elements may stabilize the HHRz in a catalytically active conformation via tertiary interactions. HHRzs stabilized by these interactions cleave efficiently at physiological Mg2+ concentrations and are functional in vivo. The proposed role of these tertiary interacting motifs is supported by mutational, functional, structural and molecular modeling analysis of natural HHRzs.     

Allosteric hammerhead ribozyme TRAPs

A new mode of allosteric regulation of nucleic acid enzymes is described and shown to operate effectively with hammerhead ribozymes. In the "TRAP" design (for targeted ribozyme-attenuated probe), a 3' terminal "attenuator" anneals to conserved bases in the catalytic core to form the "off" state of the ribozyme. Binding of RNA or DNA to an antisense sequence linking the ribozyme and attenuator frees the core to fold into an active conformation, even though the antisense sequence itself does not interfere with the ribozyme. TRAP hammerheads based on the previously characterized HH8 ribozyme were shown to be activated more than 250-fold upon addition of the sense strand. RNA oligonucleotides were more effective activators than DNA oligos, consistent with the known relative helix stabilities (RNA-RNA > RNA-DNA). Oligonucleotides that directly paired with the attenuator gave up to 1760-fold activation. The magnitude of the activation was greater when the oligo was added prior to folding than if it was added during the cleavage reaction. The TRAP design requires no prior knowledge of (deoxy)ribozyme structure beyond identification of the essential core. Thus, this approach should be readily generalizable to other systems for biomedicine, sensor technology, and additional applications.     

A re-investigation of the thio effect at the hammerhead cleavage site.

The effect of introducing a phosphorothioate at the hammerhead cleavage site was investigated using a kinetically well-characterized hammerhead. In buffers containing Mg ion, the RP-phosphorothioate isomer cleaved 2000- to 80 000-fold slower than the SPisomer or the unmodified RNA substrate. Addition of low concentrations of several thiophilic metal ions, especially Cd2+, to these reactions is sufficient to fully restore the cleavage rate of the RPsubstrate without affecting cleavage rate of the all-oxygen or SPsubstrate. Thus, a model proposing coordination of a divalent metal ion to the pro-R oxygen at the hammerhead cleavage site appears justified.     

Hammerhead redux: Does the new structure fit the old biochemical data?

The cleavage rates of 78 hammerhead ribozymes containing structurally conservative chemical modifications were collected from the literature and compared to the recently determined crystal structure of the Schistosoma mansoni hammerhead. With only a few exceptions, the biochemical data were consistent with the structure, indicating that the new structure closely resembles the transition state of the reaction. Since all the biochemical data were collected on minimal hammerheads that have a very different structure, the minimal hammerhead must be dynamic and occasionally adopt the quite different extended structure in order to cleave.     

The Global Conformation of an Active Hammerhead RNA during the Process of Self-cleavage

The RNA “hammerhead” domain is a small element of secondary structure found in the genomes of certain plant pathogens. It possesses a core of conserved sequence at the conjunction of three helix stems, and is capable of undergoing self-cleavage in the presence of divalent cations. Both crystallographic and solution studies suggest that the domain is highly structured, with the three stems assuming a Y-shaped global conformation; however, such studies have employed either RNA analogues that were catalytically inactive, or conditions of temperature and pH for which rates of self-cleavage are slow. Thus, it was unknown whether such species represented the principal conformers during the cleavage process itself. In order to address this issue, a series of time- resolved, transient electric birefringence measurements was conducted in an effort to define the global conformation of an RNA hammerhead in real time throughout the process of self-cleavage. The current study demonstrates that the angular relationship between the two helices that flank the cleavage center is essentially unchanged between the pre-cleavage and post-cleavage forms. Moreover, despite the fact that at least one kinetic intermediate is formed during the self-cleavage reaction, there is no evidence for the existence of a significant population of intermediates with altered global conformation during cleavage. Thus, any conformational isomerism that may occur is likely to be relatively localized to the active center. Finally, it was observed that sequence elements lying outside of the conserved region, at the base of stem I, influence interhelix geometry. The current results are consistent with a structural model in which the active center possesses similar conformations pre-cleavage and post-cleavage. Such a model would help to explain the significant rate of reversal of the cleavage reaction (self-ligation).     

When to believe what you see

The recent X-ray crystal structure of a hammerhead ribozyme derived from Schistosoma mansoni containing the rate-enhancing peripheral domain has a catalytic core that is very different from the catalytic core present in the structure of the "minimal" hammerhead, which lacks a peripheral domain (Martick and Scott, 2006). The new structure reconciles many of the disagreements between the minimal hammerhead structure and the biochemical data on the cleavage properties of chemically modified hammerheads. The new structure also emphasizes the dynamic nature of small RNA domains and provides a cautionary tale for everyone who tries to use structure to understand function.     

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.