Folding of the HDV antigenomic ribozyme pseudoknot structure deduced from long-range photocrosslinks.

A trans-acting system has been designed in order to explore the three-dimensional structure of the anti-genomic HDV ribozyme. In this system, the substrate (SANT) is associated by base-pairing to the catalytic RNA (RzANT) forming helix H1. RzANT is able to cleave specifically the RNA substrate as well as a deoxysubstrate analogue containing a single ribocytidine at the cleavage site (position -1). This demonstrates that such deoxysubstrate analogues are valuable tools for structural studies of this ribozyme domain. They form however weak complexes with RzANT which is due in part to their ability to fold as stable hairpins unlike the RNA substrate. Using a set of full deoxy or of mixed deoxy-ribo substrate analogues site-specific substituted with the photoaffinity probe deoxy-4-thiouridine, ds4U, at a defined position, we were able to determine a number of long range contacts between the substrate and the ribozyme core. In particular, crosslinks between substrate position -1 and position -2 with residues C15, G19 and C67, thought to be involved in the ribozyme catalytic site, were detected. A three dimensional model of the antigenomic ribozyme system, derived from the structure proposed by Tanner et al. [Current Biol (1994) 4, 488-498] for the genomic system was constructed. Apart from residue deletion or insertion, only minor accommodations were needed to account for all photocrosslinks but one which is attributed to an alternative hybridization of the substrate with the ribozyme. This study therefore further supports the structure proposed by Tanner et al. for the pseudoknot model.     

HDV ribozyme activity in monovalent cations

Activity of the two ribozymes from hepatitis delta virus in monovalent salts was examined and compared to activity in Mg2+. Both ribozymes self-cleaved in high concentrations of monovalent cations, and an active site cytosine was required for cleavage activity under those conditions. Cleavage rates were 30-50-fold higher for reactions in LiCl than for reactions in NaCl or NH4Cl, and a thio effect indicated that chemistry was rate-determining for cleavage of the HDV genomic ribozyme in LiCl. Still, in LiCl, there was a more than 100-fold increase in the rate when MgCl2 was included in the reaction. However, the pH-rate profiles for the reactions in LiCl with and without MgCl2 were both bell-shaped with the pH optima in the neutral range. These findings support the idea that monovalent cations can partially substitute for divalent metal ions in the HDV ribozymes, although a divalent metal ion is more effective in supporting catalysis. The absence of a dramatic change in the general shape of pH-rate profiles in LiCl, relative to the profile for reactions including Mg2+, is in contrast to earlier data for the reactions in NaCl and limits our interpretation of the specific role played by the divalent metal ion in the catalytic mechanism.     

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.     

Developing three-dimensional models of putative-folding intermediates of the HDV ribozyme

Both the role and the interacting partners of an RNA molecule can change depending on its tertiary structure. Consequently, it is important to be able to accurately predict the complete folding pathway of an RNA molecule. The hepatitis delta virus (HDV) ribozyme is a small catalytic RNA with the greatest number of folding intermediates making it the model of choice with which to address this problem. The tertiary structures of the known putative intermediates along the folding pathway of the HDV ribozyme were predicted using the Macromolecular Conformations Symbolic programming (MC-Sym) software. The structures obtained by this method received physical support from Selective 2'-Hydroxyl Acylation analyzed by Primer Extension (SHAPE). The analysis of these structures elucidated several features of the HDV ribozyme. In addition, this report represents an application for MC-Sym that permits progression one step further toward the computer prediction of an RNA molecule-folding pathway.     

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

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

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.     

Self-cleavage activity of the genomic HDV ribozyme in the presence of various divalent metal ions.

To identify the divalent metal ions that can support the self-cleavage activity of the genomic ribozyme of human hepatitis delta virus (HDV), we tested the activity of various divalent metal ions in the ribozyme reactions catalyzed by HDV88 (683-770 nt) and 88DI3 (HDV88 with the sequence from 740-752 nt deleted). Among various metal ions tested, Mg2+, Mn2+, Ca2+ and Sr2+ efficiently supported the self-cleavage reactions of the HDV88 and 88DI3 ribozymes. In the case of the 88DI3 ribozyme, other divalent metal ions, such as Cd2+, Ba2+, Co2+, Pb2+ and Zn2+, were also able to support the self-cleavage reaction to some extent (< 10%). In the presence of spermidine (0.5 mM), the cleavage reaction was promoted at lower concentrations of effective divalent metal ions. The HDV ribozyme represents the only example of ribozyme to date of a ribozyme that catalyzes the self-cleavage reaction in the presence of Ca2+ ions as efficiently as it does in the presence of Mg2+ ions.     

Properties of antigenomic HDV ribozyme consisting of two RNA chains

B : LS ribozyme, a trans-variant of naturally occurring HDV ribozyme, has been constructed. The ribozyme consists of a substrate-containing LS chain and an enzyme B chain and differs from previously constructed trans-ribozymes in the length and nucleotide sequence of its oligonucleotide chains (34 and 33 bp, respectively). The chains readily associate with each other at a room temperature while the LS cleavage reaction at this temperature is negligible slow, which allowed us to investigate the association of the intact chains. At the same time the self-cleavage rate constant for the trans-ribozyme B : LS at 50 degrees C is close to those for the previously studied permuted cis-ribozymes, especially LSB variant. In addition, the dependence on the reaction conditions (Mg2+ concentration, pH, temperature) of the trans-ribozyme was similar to that of cis-ribozyme. Similar to other trans-ribozymes, B : LS ribozyme demonstrates the ability for multiple use of the enzyme B-chain with an excess of the substrate LS chain. The kinetics model of self-cleavage reaction for B : LS is presented in http://www.cardio.ru/labgen/RZ_r.html. Taken together, our results show that the original trans-variant of HDV ribozyme can be used as a model for the investigation of self-cleavage process of HDV ribozymes.     

The mechanism of acidic hydrolysis of esters explains the HDV ribozyme activity

The hepatitis delta virus (HDV) ribozyme is an RNA enzyme that catalyzes the site-specific trans-esterification reaction. Using high hydrostatic pressure (HHP) technique we showed that HDV ribozyme catalyzes the reaction of RNA cleavage in the absence of magnesium ions according to mechanism of acidic hydrolysis of esters. HHP induces changes of water structure, lowering pH and effect ribozyme catalytic site structure formation without magnesium. HHP, similarly to magnesium ion at ambient pressure stabilizes the higher order RNA structure of HDV, but Mg²⁺ is not involved in the catalysis. Our results clearly support the new mechanism of HDV hydrolysis and show advantages of using HHP in analysis of macromolecules interaction.     

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

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

Importance of short pseudoknot base pairs between two single-stranded regions of HDV ribozyme.

Human hepatitis delta virus (HDV) ribozyme can catalyze self-cleavage reaction in the presence of Mg2+ ions, yielding products with 2',3'-cyclic phosphate and 5'-OH termini as do hammerhead and hairpin ribozymes. Recently, the tertiary structure of 3'-cleaved product of genomic HDV ribozyme was solved by X-ray crystallographic analysis. In this structure three single-stranded regions (SSrA, -B and -C) interacts intricately with hydrogen bonds between bases, phosphate oxygens and 2'-OHs to form nested double pseudoknot structure. Especially two Watson-Crick base pairs, 726G-710C and 727G-709C, between SSrA and SSrC, seems to be important for compact folding. To characterize the necessity of the two base pairs, we performed in vitro selection of active ribozymes using random RNA pool which mutated at 709, 710, 726 and 727. The result indicates that basically one G-C base pair is necessary for the activity.     

Activation of PKR by RNA misfolding: HDV ribozyme dimers activate PKR

Protein Kinase R (PKR), the double-stranded RNA (dsRNA)-activated protein kinase, plays important roles in innate immunity. Previous studies have shown that PKR is activated by long stretches of dsRNA, RNA pseudoknots, and certain single-stranded RNAs; however, regulation of PKR by RNAs with globular tertiary structure has not been reported. In this study, the HDV ribozyme is used as a model of a mostly globular RNA. In addition to a catalytic core, the ribozyme contains a peripheral 13-bp pairing region (P4), which, upon shortening, affects neither the catalytic activity of the ribozyme nor its ability to crystallize. We report that the HDV ribozyme sequence alone can activate PKR. To elucidate the RNA structural basis for this, we prepared a number of HDV variants, including those with shortened or lengthened P4 pairing regions, with the anticipation that lengthening the P4 extension would yield a more potent activator since it would offer more base pairs of dsRNA. Surprisingly, the variant with a shortened P4 was the most potent activator. Through native gel mobility and enzymatic structure mapping experiments we implicate misfolded HDV ribozyme dimers as the PKR-activating species, and show that the shortened P4 leads to enhanced occupancy of the RNA dimer. These observations have implications for how RNA misfolding relates to innate immune response and human disease.     

Nuclear magnetic resonance studies of the hammerhead ribozyme domain. Secondary structure formation and magnesium ion dependence

Proton nuclear magnetic resonance (n.m.r.) experiments were used to probe base-pair formation in several hammerhead RNA enzyme (ribozyme) domains. The hammerhead domains consist of a 34 nucleotide ribozyme bound to a complementary 13 nucleotide non-cleavable DNA substrate. Three hammerhead domains were studied that differ in the sequence and stability of one of the helices involved in recognition of the substrate by the ribozyme. The n.m.r. data show a 1:1 stoichiometry for the ribozyme-substrate complexes. The imino proton resonances in the hammerhead complexes were assigned by two-dimensional nuclear Overhauser effect experiments. These data confirm the presence of two of the three helical regions in the hammerhead domain, predicted from phylogenetic data; and are also consistent with the formation of the third helix. Since a divalent cation is required for efficient catalytic activity of the hammerhead domain, the magnesium ion dependence of the n.m.r. spectra was studied for two of the hammerhead complexes. One of the complexes showed very large spectral changes upon addition of magnesium ions. However, the complex that has the most C.G base-pairs in one of the recognition helices shows essentially no spectral (and therefore presumably structural) changes upon addition of magnesium. These data are consistent with a model where the magnesium binding site already exists in the magnesium-free complex, suggesting that the magnesium ion serves primarily a catalytic, and not a structural, role under the conditions used here.     

Identification of important bases for the self-cleavage activity at two single-stranded regions of genomic HDV ribozyme.

In order to determine important bases at two single-stranded regions [SSrA (726-731 nt) and SSrB (762-766)] derived mainly from secondary structure models in genomic hepatitis delta virus (HDV) ribozyme possessing self-cleavage activity, we have constructed several point mutants at these two regions on the HDV88 molecule (683-770). Among the bases at SSrA and SSrB regions C763 was found to play an essential role during self-cleavage process since substitutions to any other bases viz. A or G or U completely abolished the activity.     

Core sequences and a cleavage site wobble pair required for HDV antigenomic ribozyme self-cleavage.

The secondary structures proposed for the cis-acting hepatitis delta virus (HDV) ribozymes contain four duplex regions, three sequences joining the duplexes and two hairpin loops. The core and active site of the ribozyme could be formed by portions of the joining sequences, J1/4 and J4/2, together with one of the hairpin loops, L3. To establish the core region and define essential bases within this putative active site 28 single base changes at 15 positions were made and tested for effects on ribozyme cleavage. At 14 of the 15 positions all of the changes resulted in detectable decreased rates of cleavage. At seven of the positions one or more of the changes resulted in a 500-fold or greater decrease in the observed rate constant for cleavage. Mutations that resulted in 10(3)-fold effects were found in all three regions hypothesized to form the core. At the cleavage site substitutions of the cytosine 5' of the site of cleavage did not provide strong support for a sequence-specific interaction involving this nucleotide. In contrast, an A-C combination was the most effective substitution for a potential G-U pair 3' of the cleavage site, suggesting a requirement for a wobble pair at that position.