Catalytic core structure of the trans-acting HDV ribozyme is subtly influenced by sequence variation outside the core

The human pathogenic hepatitis delta virus (HDV) employs a unique self-cleaving catalytic RNA motif, the HDV ribozyme, during double-rolling circle replication. Fluorescence spectroscopy, circular dichroism, terbium(III) footprinting, and X-ray crystallography of precursor and product forms have revealed that a conformational change accompanies catalysis. In addition, fluorescence resonance energy transfer (FRET) has previously been used on a trans-acting HDV ribozyme to demonstrate surprisingly significant catalytic and global conformational effects of substrate analogues with varying 5' sequences, which reside as dangling overhangs outside the catalytic core. Here, we use the fluorescent guanine analogue 2-aminopurine (AP) in nucleotide position 76, immediately downstream of the catalytically involved C75, to monitor the relative structural effects of these substrate analogues on the ribozyme's trefoil turn of the catalytic core. Steady-state and time-resolved AP fluorescence spectroscopies show that the binding of each substrate analogue induces a unique local conformation with a specific AP76 stacking equilibrium. Binding of the 3' product results in a relative increase in AP fluorescence, suggesting that AP76 becomes more unstacked upon catalysis. These local conformational changes are kinetically concomitant with global conformational changes monitored by FRET. Finally, the rate constant of the local conformational change upon 3' product binding is fast and independent of 3' product concentration yet Mg2+ dependent. Our results demonstrate that the trefoil turn of the HDV ribozyme catalytic core is in a state of dynamic equilibrium not captured by static crystal structures and is highly sensitive to the identity of the 5' sequence and Mg2+ ions.     

Terbium-mediated footprinting probes a catalytic conformational switch in the antigenomic hepatitis delta virus ribozyme

The two forms of the hepatitis delta virus ribozyme are derived from the genomic and antigenomic RNA strands of the human hepatitis delta virus (HDV), where they serve a crucial role in pathogen replication by catalyzing site-specific self-cleavage reactions. The HDV ribozyme requires divalent metal ions for formation of its tertiary structure, consisting of a tight double-nested pseudoknot, and for efficient self- (or cis-) cleavage. Comparison of recently solved crystal structures of the cleavage precursor and 3' product indicates that a significant conformational switch is required for catalysis by the genomic HDV ribozyme. Here, we have used the lanthanide metal ion terbium(III) to footprint the precursor and product solution structures of the cis-acting antigenomic HDV ribozyme. Inhibitory Tb(3+) binds with high affinity to similar sites on RNA as Mg(2+) and subsequently promotes slow backbone scission. We find subtle, yet significant differences in the terbium(III) footprinting pattern between the precursor and product forms of the antigenomic HDV ribozyme, consistent with differences in conformation as observed in the crystal structures of the genomic ribozyme. In addition, UV melting profiles provide evidence for a less tight tertiary structure in the precursor. In both the precursor and product we observe high-affinity terbium(III) binding sites in joining sequence J4/2 (Tb(1/2) approximately 4 microM) and loop L3, which are key structural components forming the catalytic core of the HDV ribozyme, as well as in several single-stranded regions such as J1/2 and the L4 tetraloop (Tb(1/2) approximately 50 microM). Sensitized luminescence spectroscopy confirms that there are at least two affinity classes of Tb(3+) binding sites. Our results thus demonstrate that a significant conformational change accompanies catalysis in the antigenomic HDV ribozyme in solution, similar to the catalytic conformational switch observed in crystals of the genomic form, and that structural and perhaps catalytic metal ions bind close to the catalytic core.     

Reaction pathway of the trans-acting hepatitis delta virus ribozyme: a conformational change accompanies catalysis.

The hepatitis delta virus (HDV), an infectious human pathogen and satellite of hepatitis B virus, leads to intensified disease symptoms, including progression to liver cirrhosis. Both the circular RNA genome of HDV and its complementary antigenome contain the same cis-cleaving catalytic RNA motif that plays a crucial role in virus replication. Previously, the high-resolution crystal structure of the product form of a cis-acting genomic HDV ribozyme has been determined, while a trans-acting version of the ribozyme was used to dissect the cleavage reaction pathway. Using fluorescence resonance energy transfer (FRET) on a synthetic trans-cleaving form of the ribozyme, we are able to directly observe substrate binding (at a rate constant k(on) of 7.8 x 10(6) M(-1) min(-1) at pH 7.5, 11 mM MgCl(2), and 25 degrees C) and dissociation (at 0.34 min(-1)). Steady-state and time-resolved FRET experiments in solution and in nondenaturing gels reveal that the substrate (precursor) complex is slightly more compact (by approximately 3 A) than the free ribozyme, yet becomes significantly extended (by approximately 15 A) upon cleavage and product complex formation. We also find that trans cleavage is characterized by a high transition-state entropy (-26 eu). We propose that the significant global conformational change that we observe between the precursor and product structures occurs on the reaction trajectory into a constrained product complex-like transition state. Our observations may present the structural basis of the recently described utilization of intrinsic substrate binding energy to the overall catalytic rate enhancement by the trans-acting HDV ribozyme.     

Magnesium dependence of the amplified conformational switch in the trans-acting hepatitis delta virus ribozyme

The ability of divalent metal ions to participate in both structure formation and catalytic chemistry of RNA enzymes (ribozymes) has made it difficult to separate their cause and effect in ribozyme function. For example, the recently solved crystal structures of precursor and product forms of the cis-cleaving genomic hepatitis delta virus (HDV) ribozyme show a divalent metal ion bound in the active site that is released upon catalysis due to an RNA conformational change. This conformational switch is associated with a repositioning of the catalytically involved base C75 in the active-site cleft, thus controlling catalysis. These findings confirm previous data from fluorescence resonance energy transfer (FRET) on a trans-acting form of the HDV ribozyme that found a global conformational change to accompany catalysis. Here, we further test the conformational switch model by measuring the Mg(2+) dependence of the global conformational change of the trans-acting HDV ribozyme, using circular dichroism and time-resolved FRET as complementary probes of secondary and tertiary structure formation, respectively. We observe significant differences in both structure and Mg(2+) affinity of the precursor and product forms, in the presence and absence of 300 mM Na(+) background. The precursor shortens while the product extends with increasing Mg(2+) concentration, essentially amplifying the structural differences observed in the crystal structures. In addition, the precursor has an approximately 2-fold and approximately 13-fold lower Mg(2+) affinity than the product in secondary and tertiary structure formation, respectively. We also have compared the C75 wild-type with the catalytically inactive C75U mutant and find significant differences in global structure and Mg(2+) affinity for both their precursor and product forms. Significantly, the Mg(2+) affinity of the C75 wild-type is 1.7-2.1-fold lower than that of the C75U mutant, in accord with the notion that C75 is essential for a catalytic conformational change that leads to a decrease in the local divalent metal ion affinity and release of a catalytic metal. Thus, a consistent picture emerges in which divalent metal ions and RNA functional groups are intimately intertwined in affecting structural dynamics and catalysis in the HDV ribozyme.     

Local conformational changes in the catalytic core of the trans-acting hepatitis delta virus ribozyme accompany catalysis

The hepatitis delta virus (HDV) is a human pathogen and satellite RNA of the hepatitis B virus. It utilizes a self-cleaving catalytic RNA motif to process multimeric intermediates in the double-rolling circle replication of its genome. Previous kinetic analyses have suggested that a particular cytosine residue (C(75)) with a pK(a) close to neutrality acts as a general acid or base in cleavage chemistry. The crystal structure of the product form of a cis-acting HDV ribozyme shows this residue positioned close to the 5'-OH leaving group of the reaction by a trefoil turn in the RNA backbone. By modifying G(76) of the trefoil turn of a synthetic trans-cleaving HDV ribozyme to the fluorescent 2-aminopurine (AP), we can directly monitor local conformational changes in the catalytic core. In the ribozyme-substrate complex (precursor), AP fluorescence is strongly quenched, suggesting that AP(76) is stacked with other bases and that the trefoil turn is not formed. In contrast, formation of the product complex upon substrate cleavage or direct product binding results in a significant increase in fluorescence, consistent with AP(76) becoming unstacked and solvent-exposed as evidenced in the trefoil turn. Using AP fluorescence and fluorescence resonance energy transfer (FRET) in concert, we demonstrate that this local conformational change in the trefoil turn is kinetically coincidental with a previously observed global structural change of the ribozyme. Our data show that, at least in the trans-acting HDV ribozyme, C(75) becomes positioned for reaction chemistry only along the trajectory from precursor to product.     

Disparate HDV ribozyme crystal structures represent intermediates on a rugged free-energy landscape

The hepatitis delta virus (HDV) ribozyme is a member of the class of small, self-cleaving catalytic RNAs found in a wide range of genomes from HDV to human. Both pre- and post-catalysis (precursor and product) crystal structures of the cis-acting genomic HDV ribozyme have been determined. These structures, together with extensive solution probing, have suggested that a significant conformational change accompanies catalysis. A recent crystal structure of a trans-acting precursor, obtained at low pH and by molecular replacement from the previous product conformation, conforms to the product, raising the possibility that it represents an activated conformer past the conformational change. Here, using fluorescence resonance energy transfer (FRET), we discovered that cleavage of this ribozyme at physiological pH is accompanied by a structural lengthening in magnitude comparable to previous trans-acting HDV ribozymes. Conformational heterogeneity observed by FRET in solution appears to have been removed upon crystallization. Analysis of a total of 1.8 µsec of molecular dynamics (MD) simulations showed that the crystallographically unresolved cleavage site conformation is likely correctly modeled after the hammerhead ribozyme, but that crystal contacts and the removal of several 2′-oxygens near the scissile phosphate compromise catalytic in-line fitness. A cis-acting version of the ribozyme exhibits a more dynamic active site, while a G-1 residue upstream of the scissile phosphate favors poor fitness, allowing us to rationalize corresponding changes in catalytic activity. Based on these data, we propose that the available crystal structures of the HDV ribozyme represent intermediates on an overall rugged RNA folding free-energy landscape.     

Long-range impact of peripheral joining elements on structure and function of the hepatitis delta virus ribozyme

The HDV ribozyme is an RNA enzyme from the human pathogenic hepatitis delta virus (HDV) that has recently also been identified in the human genome. It folds into a compact, nested double-pseudoknot. We examined here the functional relevance of the capping loop L4 and the helical crossover J1/2, which tightly interlace the two helical stacks of the ribozyme. Peripheral structural elements such as these are present in cis-acting, but not trans-acting ribozymes, which may explain the order-of-magnitude decrease in cleavage activity observed in trans-acting ribozymes with promise in gene therapy applications. Comparison of a systematic set of cis- and trans-acting HDV ribozymes shows that the absence of either L4 or J1/2 significantly and independently impacts catalytic activity. Using terbium(III) footprinting and affinity studies, as well as distance measurements based on time-resolved fluorescence resonance energy transfer, we find that J1/2 is most important for conferring structural properties similar to those of the cis-acting ribozyme. Our results are consistent with a model in which removal of either a helical crossover or surprisingly a capping loop induces greater dynamics and expansion of the catalytic core at long range, impacting local and global folding, as well as catalytic function.     

Energetic contribution of non-essential 5' sequence to catalysis in a hepatitis delta virus ribozyme

Hepatitis delta virus (HDV) ribozymes employ multiple catalytic strategies to achieve overall rate enhancement of RNA cleavage. These strategies include general acid-base catalysis by a cytosine side chain and involvement of divalent metal ions. Here we used a trans-acting form of the antigenomic ribozyme to examine the contribution of the 5' sequence in the substrate to HDV ribozyme catalysis. The cleavage rate constants increased for substrates with 5' sequence alterations that reduced ground-state binding to the ribozyme. Quantitatively, a plot of activation free energy of chemical conversion versus Gibb's free energy of substrate binding revealed a linear relationship with a slope of -1. This relationship is consistent with a model in which components of the substrate immediately 5' to the cleavage site in the HDV ribozyme-substrate complex destabilize ground-state binding. The intrinsic binding energy derived from the ground-state destabilization could contribute up to 2 kcal/mol toward the total 8.5 kcal/mol reduction in activation free energy for RNA cleavage catalyzed by the HDV ribozyme.     

Structural dynamics of precursor and product of the RNA enzyme from the hepatitis delta virus as revealed by molecular dynamics simulations

The hepatitis delta virus (HDV) ribozyme is a self-cleaving RNA enzyme involved in the replication of a human pathogen, the hepatitis delta virus. Recent crystal structures of the precursor and product of self-cleavage, together with detailed kinetic analyses, have led to hypotheses on the catalytic strategies employed by the HDV ribozyme. We report molecular dynamics (MD) simulations (approximately 120 ns total simulation time) to test the plausibility that specific conformational rearrangements are involved in catalysis. Site-specific self-cleavage requires cytidine in position 75 (C75). A precursor simulation with unprotonated C75 reveals a rather weak dynamic binding of C75 in the catalytic pocket with spontaneous, transient formation of a H-bond between U-1(O2') and C75(N3). This H-bond would be required for C75 to act as the general base. Upon protonation in the precursor, C75H+ has a tendency to move towards its product location and establish a firm H-bonding network within the catalytic pocket. However, a C75H+(N3)-G1(O5') H-bond, which would be expected if C75 acted as a general acid catalyst, is not observed on the present simulation timescale. The adjacent loop L3 is relatively dynamic and may serve as a flexible structural element, possibly gated by the closing U20.G25 base-pair, to facilitate a conformational switch induced by a protonated C75H+. L3 also controls the electrostatic environment of the catalytic core, which in turn may modulate C75 base strength and metal ion binding. We find that a distant RNA tertiary interaction involving a protonated cytidine (C41) becomes unstable when left unprotonated, leading to disruptive conformational rearrangements adjacent to the catalytic core. A Na ion temporarily compensates for the loss of the protonated hydrogen bond, which is strikingly consistent with the experimentally observed synergy between low pH and high Na+ concentrations in mediating residual self-cleavage of the HDV ribozyme in the absence of divalents.     

In the fluorescent spotlight: global and local conformational changes of small catalytic RNAs

RNA is a ubiquitous biopolymer that performs a multitude of essential cellular functions involving the maintenance, transfer, and processing of genetic information. RNA is unique in that it can carry both genetic information and catalytic function. Its secondary structure domains, which fold stably and independently, assemble hierarchically into modular tertiary structures. Studies of these folding events are key to understanding how catalytic RNAs (ribozymes) are able to position reaction components for site-specific chemistry. We have made use of fluorescence techniques to monitor the rates and free energies of folding of the small hairpin and hepatitis delta virus (HDV) ribozymes, found in satellite RNAs of plant and the human hepatitis B viruses, respectively. In particular, fluorescence resonance energy transfer (FRET) has been employed to monitor global conformational changes, and 2-aminopurine fluorescence quenching to probe for local structural rearrangements. In this review we illuminate what we have learned about the reaction pathways of the hairpin and HDV ribozymes, and how our results have complemented other biochemical and biophysical investigations. The structural transitions observed in these two small catalytic RNAs are likely to be found in many other biological RNAs, and the described fluorescence techniques promise to be broadly applicable.     

A base change in the catalytic core of the hairpin ribozyme perturbs function but not domain docking

The hairpin ribozyme is a small endonucleolytic RNA motif with potential for targeted RNA inactivation. It optimally cleaves substrates containing the sequence 5'-GU-3' immediately 5' of G. Previously, we have shown that tertiary structure docking of its two domains is an essential step in the reaction pathway of the hairpin ribozyme. Here we show, combining biochemical and fluorescence structure and function probing techniques, that any mutation of the substrate base U leads to a docked RNA fold, yet decreases cleavage activity. The docked mutant complex shares with the wild-type complex a common interdomain distance as measured by time-resolved fluorescence resonance energy transfer (FRET) as well as the same solvent-inaccessible core as detected by hydroxyl-radical protection; hence, the mutant complex appears nativelike. FRET experiments also indicate that mutant docking is kinetically more complex, yet with an equilibrium shifted toward the docked conformation. Using 2-aminopurine as a site-specific fluorescent probe in place of the wild-type U, a local structural rearrangement in the substrate is observed. This substrate straining accompanies global domain docking and involves unstacking of the base and restriction of its conformational dynamics, as detected by time-resolved 2-aminopurine fluorescence spectroscopy. These data appear to invoke a mechanism of functional interference by a single base mutation, in which the ribozyme-substrate complex becomes trapped in a nativelike fold preceding the chemical transition state.     

Structural roles of monovalent cations in the HDV ribozyme

The hepatitis delta virus (HDV) ribozyme catalyzes viral RNA self-cleavage through general acid-base chemistry in which an active-site cytidine and at least one metal ion are involved. Monovalent metal ions support slow catalysis and were proposed to substitute for structural, but not catalytic, divalent metal ions in the RNA. To investigate the role of monovalent cations in ribozyme structure and function, we determined the crystal structure of the precursor HDV ribozyme in the presence of thallium ions (Tl(+)). Two Tl(+) ions can occupy a previously observed divalent metal ion hexahydrate-binding site located near the scissile phosphate, but are easily competed away by cobalt hexammine, a magnesium hexahydrate mimic and potent reaction inhibitor. Intriguingly, a third Tl(+) ion forms direct inner-sphere contacts with the ribose 2'-OH nucleophile and the pro-S(p) scissile phosphate oxygen. We discuss possible structural and catalytic implications of monovalent cation binding for the HDV ribozyme mechanism.     

A circular trans-acting hepatitis delta virus ribozyme.

A circular trans-acting ribozyme designed to adopt the motif of the hepatitis delta virus (HDV) trans-acting ribozyme was produced. The circular form was generated in vitro by splicing a modified group I intron precursor RNA in which the relative order of the 5' and 3' splice sites, flanking the single HDV-like ribozyme sequence-containing exon, is reversed. Trans-cleavage activity of the circular HDV-like ribozyme was comparable to linear permutations of HDV ribozymes containing the same core sequence, and was shown not to be due to linear contaminants in the circular ribozyme preparation. In nuclear and cytoplasmic extracts from HeLa cells, the circular ribozyme had enhanced resistance to nuclease degradation relative to a linear form of the ribozyme, suggesting that circularization may be a viable alternative to chemical modification as a means of stabilizing ribozymes against nuclease degradation.     

Trans-acting glmS catalytic riboswitch: locked and loaded

A recently discovered class of gene regulatory RNAs, coined riboswitches, are commonly found in noncoding segments of bacterial and some eukaryotic mRNAs. Gene up- or down-regulation is triggered by binding of a small organic metabolite, which typically induces an RNA conformational change. Unique among these noncoding RNAs is the glmS catalytic riboswitch, or ribozyme, found in the 5'-untranslated region of the glmS gene in Gram-positive bacteria. It is activated by glucosamine-6-phosphate (GlcN6P), leading to site-specific backbone cleavage of the mRNA and subsequent repression of the glmS gene, responsible for cellular GlcN6P production. Recent biochemical and structural evidence suggests that the GlcN6P ligand acts as a coenzyme and participates in the cleavage reaction without inducing a conformational change. To better understand the role of GlcN6P in solution structural dynamics and function, we have separated the glmS riboswitch core from Bacillus subtilis into a trans-cleaving ribozyme and an externally cleaved substrate. We find that trans cleavage is rapidly activated by nearly 5000-fold to a rate of 4.4 min(-1) upon addition of 10 mM GlcN6P, comparable to the cis-acting ribozyme. Fluorescence resonance energy transfer suggests that this ribozyme-substrate complex does not undergo a global conformational change upon ligand binding in solution. In addition, footprinting at nucleotide resolution using terbium(III) and RNase V1 indicates no significant changes in secondary and tertiary structure upon ligand binding. These findings suggest that the glmS ribozyme is fully folded in solution prior to binding its activating ligand, supporting recent observations in the crystalline state.     

Delta ribozyme has the ability to cleave in transan mRNA.

We report here the first demonstration of the cleavage of an mRNA in trans by delta ribozyme derived from the antigenomic version of the human hepatitis delta virus (HDV). We characterized potential delta ribozyme cleavage sites within HDV mRNA sequence (i.e. C/UGN6), using oligonucleotide binding shift assays and ribonuclease H hydrolysis. Ribozymes were synthesized based on the structural data and then tested for their ability to cleave the mRNA. Of the nine ribozymes examined, three specifically cleaved a derivative HDV mRNA. All three active ribozymes gave consistent indications that they cleaved single-stranded regions. Kinetic characterization of the ability of ribozymes to cleave both the full-length mRNA and either wild-type or mutant small model substrate suggests: (i) delta ribozyme has turnovers, that is to say, several mRNA molecules can be successively cleaved by one ribozyme molecule; and (ii) the substrate specificity of delta ribozyme cleavage is not restricted to C/UGN6. Specifically, substrates with a higher guanosine residue content upstream of the cleavage site (i.e. positions -4 to -2) were always cleaved more efficiently than wild-type substrate. This work shows that delta ribozyme constitutes a potential catalytic RNA for further gene-inactivation therapy.     

In the fluorescent spotlight: Global and local conformational changes of small catalytic RNAs

RNA is a ubiquitous biopolymer that performs a multitude of essential cellular functions involving the maintenance, transfer, and processing of genetic information. RNA is unique in that it can carry both genetic information and catalytic function. Its secondary structure domains, which fold stably and independently, assemble hierarchically into modular tertiary structures. Studies of these folding events are key to understanding how catalytic RNAs (ribozymes) are able to position reaction components for site‐specific chemistry. We have made use of fluorescence techniques to monitor the rates and free energies of folding of the small hairpin and hepatitis delta virus (HDV) ribozymes, found in satellite RNAs of plant and the human hepatitis B viruses, respectively. In particular, fluorescence resonance energy transfer (FRET) has been employed to monitor global conformational changes, and 2‐aminopurine fluorescence quenching to probe for local structural rearrangements. In this review we illuminate what we have learned about the reaction pathways of the hairpin and HDV ribozymes, and how our results have complemented other biochemical and biophysical investigations. The structural transitions observed in these two small catalytic RNAs are likely to be found in many other biological RNAs, and the described fluorescence techniques promise to be broadly applicable. © 2002 Wiley Periodicals, Inc. Biopoly (Nucleic Acid Sci) 61: 224–241, 2002     

Secondary structure content of the HDV ribozyme in 95% formamide.

The Hepatitis Delta Virus (HDV) ribozyme self-cleaving activity in 20 M formamide solutions is unique. Does this catalytic activity result from the conservation of its tertiary structure in 20 M formamide? We followed the ribozyme structure in formamide solutions by monitoring the amount of bound Ethidium Bromide (EB). We were able to measure the quantity of dye bound using time-resolved fluorescence spectroscopy, as an estimate of the ribozyme double helical content. This method, calibrated by using oligonucleotides with defined tertiary structure and denaturing solvents, parallels NMR and UV measurements as a function of temperature. Measurements with the HDV ribozyme lead to three conclusions: (a) both the precursor and product RNAs are structured to 24 M (95% w/w) formamide or 4 M H2O solutions which is equivalent to 4 M H2O; (b) the HDV ribozyme is the only RNA sequence investigated in this study that retains so much structure in formamide; and (c) DNA analogs of formamide resistant HDV ribozyme sequences lose their structure at less than 15 M formamide. Thus, the structural integrity of the HDV ribozyme is an intrinsic property of the RNA molecule and its sequence.     

Non-ribozyme sequences enhance self-cleavage of ribozymes derived from Hepatitis delta virus.

Analysis of the self-cleavage of ribozymes derived from the genomic RNA of Hepatitis delta virus (HDV) has revealed that certain co-transcribed vector sequences significantly affect the activity of the ribozyme. Specifically, the t1/2 of self-cleavage for a 135 nucleotide HDV RNA varied, at 42 degrees C, from 5 min to 88 min, depending on the vector-derived sequences flanking the 5' end of the ribozyme. Further analysis suggested that this phenomenon was most likely due to the interaction of vector-derived sequences with a 16 nucleotide region found at the 3' end of the ribozyme. These findings have implications for studies of ribozymes transcribed from cDNA templates, and may provide information regarding the catalytic structure of the HDV ribozyme.     

Intracellular ribozyme-catalyzed trans-cleavage of RNA monitored by fluorescence resonance energy transfer

Small catalytic RNAs like the hairpin ribozyme are proving to be useful intracellular tools; however, most attempts to demonstrate trans-cleavage of RNA by ribozymes in cells have been frustrated by rapid cellular degradation of the cleavage products. Here, we describe a fluorescence resonance energy transfer (FRET) assay that directly monitors cleavage of target RNA in tissue-culture cells. An oligoribonucleotide substrate was modified to inhibit cellular ribonuclease degradation without interfering with ribozyme cleavage, and donor (fluorescein) and acceptor (tetramethylrhodamine) fluorophores were introduced at positions flanking the cleavage site. In simple buffers, the intact substrate produces a strong FRET signal that is lost upon cleavage, resulting in a red-to-green shift in dominant fluorescence emission. Hairpin ribozyme and fluorescent substrate were microinjected into murine fibroblasts under conditions in which substrate cleavage can occur only inside the cell. A strong FRET signal was observed by fluorescence microscopy when substrate was injected, but rapid decay of the FRET signal occurred when an active, cognate ribozyme was introduced with the substrate. No acceleration in cleavage rates was observed in control experiments utilizing a noncleavable substrate, inactive ribozyme, or an active ribozyme with altered substrate specificity. Subsequently, the fluorescent substrates were injected into clonal cell lines that expressed cognate or noncognate ribozymes. A decrease in FRET signal was observed only when substrate was microinjected into cells expressing its cognate ribozyme. These results demonstrate trans-cleavage of RNA within mammalian cells, and provide an experimental basis for quantitative analysis of ribozyme activity and specificity within the cell.     

Cations and hydration in catalytic RNA: molecular dynamics of the hepatitis delta virus ribozyme

The hepatitis delta virus (HDV) ribozyme is an RNA enzyme from the human pathogenic HDV. Cations play a crucial role in self-cleavage of the HDV ribozyme, by promoting both folding and chemistry. Experimental studies have revealed limited but intriguing details on the location and structural and catalytic functions of metal ions. Here, we analyze a total of approximately 200 ns of explicit-solvent molecular dynamics simulations to provide a complementary atomistic view of the binding of monovalent and divalent cations as well as water molecules to reaction precursor and product forms of the HDV ribozyme. Our simulations find that an Mg2+ cation binds stably, by both inner- and outer-sphere contacts, to the electronegative catalytic pocket of the reaction precursor, in a position to potentially support chemistry. In contrast, protonation of the catalytically involved C75 in the precursor or artificial placement of this Mg2+ into the product structure result in its swift expulsion from the active site. These findings are consistent with a concerted reaction mechanism in which C75 and hydrated Mg2+ act as general base and acid, respectively. Monovalent cations bind to the active site and elsewhere assisted by structurally bridging long-residency water molecules, but are generally delocalized.