Deletion of internal sequence on the HDV-ribozyme: elucidation of functionally important single-stranded loop regions

Long-distance communication in the HDV ribozyme: insights from molecular dynamics and experiments

The hepatitis delta virus ribozyme is a small, self-cleaving RNA with a compact tertiary structure and buried active site that is important in the life cycle of the virus. The ribozyme's function in nature is to cleave an internal phosphodiester bond and linearize concatemers during rolling circle replication. Crystal structures of the ribozyme have been solved in both pre-cleaved and post-cleaved (product) forms and reveal an intricate network of interactions that conspire to catalyze bond cleavage. In addition, extensive biochemical studies have been performed to work out a mechanism for bond cleavage in which C75 and a magnesium ion catalyze the reaction by general acid-base chemistry. One issue that has remained unclear in this ribozyme and in other ribozymes is the nature of long-distance communication between peripheral regions of the RNA and the buried active site. We performed molecular dynamics simulations on the hepatitis delta virus ribozyme in the product form and assessed communication between a distal structural portion of the ribozyme-the protonated C41 base triple-and the active site containing the critical C75. We varied the ionization state of C41 in both the wild type and a C41 double mutant variant and determined the impact on the active site. In all four cases, effects at the active site observed in the simulations agree with experimental studies on ribozyme activity. Overall, these studies indicate that small functional RNAs have the potential to communicate interactions over long distances and that wild-type RNAs may have evolved ways to prevent such interactions from interfering with catalysis.

Activation of the CKI-CDK-Rb-E2F Pathway in Full Genome Hepatitis C Virus-expressing Cells

Hepatitis C virus (HCV) causes persistent infection in hepatocytes, and this infection is, in turn, strongly associated with the development of hepatocellular carcinoma. To clarify the mechanisms underlying these effects, we established a Cre/loxP conditional expression system for the precisely self-trimmed HCV genome in human liver cells. Passage of hepatocytes expressing replicable full-length HCV (HCR6-Rz) RNA caused up-regulation of anchorage-independent growth after 44 days. In contrast, hepatocytes expressing HCV structural, nonstructural, or all viral proteins showed no significant changes after passage for 44 days. Only cells expressing HCR6-Rz passaged for 44 days displayed acceleration of CDK activity, hyperphosphorylation of Rb, and E2F activation. These results demonstrate that full genome HCV expression up-regulates the CDK-Rb-E2F pathway much more effectively than HCV proteins during passage.

Catalytic strategies of the hepatitis delta virus ribozymes

The hepatitis delta virus (HDV) ribozymes are self-cleaving RNA sequences critical to the replication of a small RNA genome. A recently determined crystal structure together with biochemical and biophysical studies provides new insight into the possible catalytic mechanism of these ribozymes. The HDV ribozymes are examples of naturally occurring small ribozymes that catalyze cleavage of the RNA backbone with a rate enhancement of 10(6)- to 10(7)-fold over the uncatalyzed rate. To achieve this level of rate enhancement, the HDV ribozymes have been proposed to employ several catalytic strategies that include the use of metal ions, intrinsic binding energy, and a novel example of general acid-base catalysis with a cytosine side chain acting as a proton donor or acceptor.

Analysis of the cleavage reaction of a trans-acting human hepatitis delta virus ribozyme

The cleavage reaction catalyzed by the trans -acting genomic ribozyme of human hepatitis delta virus (HDV) was analyzed with a 13mer substrate (R13) and thio-substituted [SR13(Rp) and SR13(Sp)] substrates under single-turnover conditions. The cleavage of RNA by the trans -acting HDV ribozyme proceeded as a first order reaction. The logarithm of the rate of cleavage (kclv) increased linearly (with a slope of approximately 1) between pH 4.0 and 6.0, an indication that a single deprotonation reaction occurred. This result suggests that kclv reflects the rate of the chemical cleavage step, at least around pH 5. The amount of active complex with the SR13(Sp) substrate was almost as large as with R13 (60-80%), whereas the amount of the corresponding active complex formed with the SR13(Rp) substrate was, at most, 20% of this value (with 0.5-100 mM Mg2+ions) at pH 5.0. Nonetheless, the value of kclv for all substrates was almost the same (0.4-0.5 min-1). Neither a 'thio effect' nor a 'Mn2+rescue effect' were observed. These results suggest that Mg2+ions do not interact with pro-R oxygen directly but are essential to the formation of the active complex of the ribozyme and its substrate.

Detailed analysis of base preferences at the cleavage site of a trans-acting HDV ribozyme: a mutation that changes cleavage site specificity

In our previous attempt at in vitro selection of a trans - acting human hepatitis delta virus (HDV) ribozyme, we found that one of the variants, G10-68-725G, cleaved a 13 nt substrate, HDVS1, at two sites [Nishikawa,F., Kawakami,J., Chiba,A., Shirai,M., Kumar,P.K.R. and Nishikawa,S. (1996) Eur. J. Biochem., 237, 712-718]. One site was the normal cleavage site and the other site was shifted 1 nt toward the 3'-end. To clarify the interactions between nucleotides around the cleavage site of the trans -acting HDV ribozyme, we analyzed the efficiency of the reaction for every possible base pair between the substrate and the ribozyme at positions -1 (-1N:726N) and +1 (+1N:725N) relative to the cleavage site using the genomic HDV ribozyme, TdS4(Xho), and derivatives of the most active variant, G10-68. These mutagenesis analyses revealed that the +1 base of the substrate affects the structure of the catalytic core in the complex with G10-68-725G, substrate and divalent metal ions, and it shifts the cleavage site. In a comparison with other variants of the trans -acting HDV ribozyme, we found that this cleavage site shift occurred only with G10-68-725G.

Selection in vitro of trans-acting genomic human hepatitis delta virus (HDV) ribozymes

In an effort to identify the functional structure as well as new active variants of the trans-acting genomic ribozyme of human hepatitis delta virus (HDV), we applied an in vitro selection procedure. A total of 14 rounds of selection and amplification was repeated and various mutant ribozymes in G10 and G14 pools analyzed. Active ribozymes which were isolated in the present study (from G10 and G14) all possessed conserved bases (that were identified earlier) in the cis-acting molecule. A dominant clone G10-68 variant was accumulated in generation 14. Interestingly, when base substitutions were analyzed in G10-68 variant, we found that this variant appears to be close to antigenome-like HDV ribozyme molecule. Further investigations of G10-68 confirmed that each mutated base was the most appropriate nucleotide at every position of the HDV ribozyme.

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.

3-D models of the antigenomic ribozyme of the hepatitis delta agent with eight new contacts suggested by sequence analysis of 188 cDNA clones

We mapped 359 mutations at 25 positions in synthetic variants of the antigenomic ribozyme of the hepatitis delta agent by analyzing the sequences of 188 cDNA clones. These data were used to identify three features of the ribozyme: highly conserved nucleotides, positions with restricted nucleotide substitutions and three-dimensional relationships between nucleotides. The distribution of mutations at the 25 positions was as follows: G-11 (the eleventh nucleotide from the cleavage site) was mutated in 56 clones; G-12 in 36; U-15 in 33; C-13 in 26; G-28 in 23; C-27 in 21; C-29 in 19; U-26 in 17; C-18 in 14; A-14 in 13; C-16 in 13; C-19 in 12; U-17 in 11; A-20 in 10; G-42 in 9; G-40 in 7; G-41 in 7; C-24 in 6; U-32 in 6; U-23 in 5; C-25 in 4; C-21 in 3; G-30 in 3; G-31 in 3; C-22 in 1. All clones containing a mutation at C-25 had an A at this position, suggesting that the extra cyclic amino group present in adenine and cytosine may function during the cleavage event. Mutations at certain positions were common in simple clones (containing only one or two mutations), while mutations at other positions were over-represented in more complex clones. Both compensatory base changes and co-mutational frequencies were used to identify eight pairs of nucleotides which may interact with each other: G-11 and C-18, G-12 and C-27, C-13 and G-28, C-21 and U-23/C-24, C-21 and G-30, U-23 and G-31/U-32, C24 and G-30, C-27 and G-42. These pairs, which involve some of the most conserved positions in the molecule, suggest interactions among nucleotides previously depicted in open-loop structures. The newly proposed points of contact between pairs of nucleotides are compatible with both the axehead and pseudoknot secondary structural models and were combined with previously proposed Watson-Crick base paired helices to produce two three dimensional models. In both of these, C-25 and C-76 are placed near the cleavage site.

Identification of phosphate oxygens that are important for self-cleavage activity of the HDV ribozyme by phosphorothioate substitution interference analysis

A phosphorothioate substitution interference assay was used to investigate the role of the pro-Rp oxygens of phosphate groups in the self-cleavage reaction of the genomic human hepatitis delta virus (HDV) ribozyme. Incorporation of several different phosphorothioates (NTP alpha S) into the HDV ribozyme inhibited the self-cleavage activity. Incorporation of uridine 5' phosphorothioate or adenosine 5' phosphorothioate maintained 72% of the original self-cleavage activity whereas incorporation of guanosine 5' phosphorothioate or cytosine 5' phosphorothioate into the precursor reduced self-cleavage activity to about 20% in each case. Using partially substituted phosphorothioate-modified transcripts, we identified the pro-Rp oxygens that are important for the ribozyme activity, and they are located at positions 0, 1, 4, 5, 21, 24, 25, 27, 28, 30-34, 40, 43 and 75. In particular, the pro-Rp oxygens at positions 0, 1 and 21 are appear to be critical for the self-cleavage activity of the HDV ribozyme.

Cis- and trans-acting ribozymes from a human pathogen, hepatitis delta virus

Hepatitis delta virus (HDV) contains two self-cleaving RNA sequences (ribozymes) that may naturally function as such in human cells. A pseudo-knot-containing structural motif, which is distinct from the well-characterized secondary structures of self-cleaving RNAs common to the plant pathogenic RNAs, is shared by the cis-acting HDV ribozymes. Definition of the sequences and secondary structures of the HDV ribozymes has facilitated the design of novel catalytic molecules, such as small RNA circles, capable of site-specific cleavage of RNA in trans.

Chemical probing studies of variants of the genomic hepatitis delta virus ribozyme by primer extension analysis

We have investigated in detail the higher order structure of the genomic hepatitis delta virus (HDV) ribozyme using various base-specific chemical probes under native, semi-denaturing, and denaturing conditions. The bases of the HDV ribozyme were probed by treatment with dimethyl sulfate [which reacts with A (at N1) and C (at N3)] and a carbodiimide [which reacts with U (at N3) and G (at N1)]. In addition, for probing G residues (at N7), RNA samples were treated with NaBH4 and aniline after modification by treatment with dimethyl sulfate. The sites of modified positions were identified by primer extension analysis with reverse transcriptase. In general, our results are consistent with the proposed pseudoknot model of secondary structure, a model that is based on data from ribonucleolytic cleavage experiments. Our results provide clues to the identification of interacting bases in the HDV ribozyme. Furthermore, using this method we identified local conformational changes in several stem variants.

Identification of important bases in a single-stranded region (SSrC) of the hepatitis delta (delta) virus ribozyme

Models for the secondary structure of genomic and antigenomic self-cleaving RNAs of human hepatitis delta (delta) virus (HDV) have been proposed by several groups. Our recent results support a pseudoknot structure and have allowed us to identify functionally important nucleotides in single-stranded regions [nucleotides 726-731 (SSrA) and nucleotides 762-766 (SSrB)]. For the identification of the important residues in the remaining single-stranded region, nucleotides 708-715 (SSrC), of the genomic HDV ribozyme, we made derivatives with a single-base substitution in the SSrC region. To screen inactive mutants rapidly, we use a simplified in-vitro selection method. Among the various base substitutions in mutants in the SSrC, U708A, C709(A/G/U) and G713C variants had less than 10% of the cleavage activity of the wild-type SSrC (HDV86). By analyzing the self-cleavage activities of various mutants, we determined the base requirements for SSrC as 5'-(U/C/G)-C-N-N-(C/A/G)-(G/A/U)-N-N-3'.

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.

Assessment of disparate structural features in three models of the hepatitis delta virus ribozyme

Three models for the secondary structure of the hepatitis delta virus (HDV) antigenomic self-cleaving RNA element were tested by site-directed mutagenesis. Two models in which bases 5' to the cleavage site are paired with sequence at the 3' end of the element were both inconsistent with the data from the mutagenesis. Specifically, mutations in the 3' sequence which decrease self-cleavage activity could not be compensated by base changes in the 5' sequence as predicted by these models. The evidence was consistent with a third model in which the 3' end pairs with a portion of a loop within the ribozyme sequence to generate a pseudoknot structure. This same pairing was also required to generate higher rates of cleavage in trans with a 15-mer ribozyme, thus ruling out a proposed hammerhead-like 'axehead' model for the HDV ribozyme.

Systematic substitution of individual bases in two important single-stranded regions of the HDV ribozyme for evaluation of the role of specific bases

To elucidate the role of specific bases in the self-cleavage activity of the human hepatitis delta virus (HDV) ribozyme, systematic substitutions of individual bases in two important single-stranded regions [between nucleotides 726-731 (SSrA region) and 762-766 (SSrB region)] were carried out by oligonucleotide-directed point mutagenesis. Among the mutants obtained, 12 mutants (G726 variants, G727A, G727C, G728C, G762A, G762C, C763 variants and A766C) could not tolerate the respective base-substitutions and self-cleavage activities were reduced to very low levels (10%), suggesting a requirement of the respective bases. In particular, G726 in the SSrA region and C763 in the SSrB region were found to be essential for the ribozyme activity. We could determine the preferred sequences, 5'-G-G-(G/A/U)-N-(A/U/G)-Pu-3' for SSrA and 5'-(G/U)-C-N-(A/G/U)-A-3' for SSrB regions, respectively.

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.

Random mutations to evaluate the role of bases at two important single-stranded regions of genomic HDV ribozyme

In elucidating function of two important single-stranded regions [SSrA (726-731 nt) and SSrB (762-766 nt)] derived mainly from three secondary structure models in genomic hepatitis delta virus (HDV) ribozyme possessing self-cleavage activity, we have constructed several random mutants at those two regions on the HDV88 molecule (683-770 nt) by oligonucleotide-directed mutagenesis. When self-cleavage activities were compared among mutants, at the region SSrA, G726 was found to play an important role during cleavage reaction since substitutions of the base to A (mutant A20) or C (mutant A16) or U (mutant A23), reduced the ribozyme activity to very low levels suggesting the importance of G726 position. C763 at SSrB region was found to play a more significant role during catalysis than G726 (at region SSrA) since any substitutions at C763 completely inactivated the ribozyme. Other bases located in these two regions could be substituted to other bases at the expense of some self-cleavage activity. The results presented here together with our previous deletion analysis indicate that these two regions may play an important role during cleavage process.