The Identity of a Single Residue of the RNA-Dependent RNA Polymerase of Grapevine Fanleaf Virus Modulates Vein Clearing in Nicotiana benthamiana.

The mechanisms underlying host plant symptom development upon infection by viruses of the genus Nepovirus in the family Secoviridae, including grapevine fanleaf virus (GFLV), are poorly understood. In the systemic host Nicotiana benthamiana, GFLV strain GHu produces characteristic symptoms of vein clearing in apical leaves, unlike other GFLV strains such as F13, which cause an asymptomatic infection. In this study, we expanded on earlier findings and used reverse genetics to identify residue 802 (lysine, K) of the GFLV-GHu RNA1-encoded RNA-dependent RNA polymerase (1EPol) as a modulator of vein-clearing symptom development in N. benthamiana. Mutations to this site abolished (K to G, A, or Q) or attenuated (K to N or P) symptom expression. Noteworthy, residue 802 is necessary but not sufficient for vein clearing, as GFLV-F13 RNA1 carrying K802 remained asymptomatic in N. benthamiana. No correlation was found between symptom expression and RNA1 accumulation, as shown by reverse transcription-quantitative polymerase chain reaction. Additionally, the involvement of RNA silencing of vein clearing was ruled out by virus-induced gene silencing experiments and structure predictions for protein 1EPol suggested that residue 802 is flanked by strongly predicted stable secondary structures, including a conserved motif of unknown function (805LLKT/AHLK/RT/ALR814). Together, these results reveal the protein nature of the GFLV-GHu symptom determinant in N. benthamiana and provide a solid basis for probing and determining the virus-host proteome network for symptoms of vein clearing.

Development of Quenching-qPCR (Q-Q) assay for measuring absolute intracellular cleavage efficiency of ribozyme.

Ribozyme (Rz) is a very attractive RNA molecule in metabolic engineering and synthetic biology fields where RNA processing is required as a control unit or ON/OFF signal for its cleavage reaction. In order to use Rz for such RNA processing, Rz must have highly active and specific catalytic activity. However, current methods for assessing the intracellular activity of Rz have limitations such as difficulty in handling and inaccuracies in the evaluation of correct cleavage activity. In this paper, we proposed a simple method to accurately measure the "intracellular cleavage efficiency" of Rz. This method deactivates unwanted activity of Rz which may consistently occur after cell lysis using DNA quenching method, and calculates the cleavage efficiency by analyzing the cleaved fraction of mRNA by Rz from the total amount of mRNA containing Rz via quantitative real-time PCR (qPCR). The proposed method was applied to measure "intracellular cleavage efficiency" of sTRSV, a representative Rz, and its mutant, and their intracellular cleavage efficiencies were calculated as 89% and 93%, respectively.

A recombinant RNA bacteriophage system to identify functionally important nucleotides in a self-cleaving ribozyme.

BACKGROUND: RNA bacteriophages like Qbeta and MS2 are well known for their high mutation rate, short infection cycle and strong selection against foreign inserts. The hammerhead ribozyme (HHRz) is a small self-cleaving RNA molecule whose active residues have previously been identified by mutational analysis of each individual base. Here the functionally important bases of HHRz were determined in a single screening experiment by inserting the HHRz into the genome of MS2. FINDINGS: The minimal HHRz of satellite Tobacco ringspot virus was cloned into the genome of RNA bacteriophage MS2. Sequence analysis of the surviving phages revealed that the majority had acquired single base-substitutions that apparently inactivated the HHRz. The positions of these substitutions exactly matched that of the previously determined core residues of the HHRz. CONCLUSIONS: Natural selection against a ribozyme in the genome of MS2 can be used to quickly identify nucleotides required for self-cleavage.

In vitro and in vivo evidence for differences in the protease activity of two arabis mosaic nepovirus isolates and their impact on the infectivity of chimeric cDNA clones.

Regulated processing of nepovirus polyproteins allows the release of mature proteins and intermediate polyproteins. Infectious cDNA clones of the mild NW isolate of arabis mosaic virus (ArMV) and chimeric clones incorporating RNA1 segments of Lv, a severe isolate, were generated. Clones containing the Lv X2-NTB cleavage site were not infectious unless the Lv protease was present. The Lv and NW X2-NTB cleavage sites differ at positions P6, P4 and P2. In vitro, processing at the X2-NTB site was undetectable or reduced in chimeric polyproteins containing the Lv X2-NTB site and the NW protease but was restored when both the Lv protease and X2-NTB site were present. In contrast, cleavage at this site was increased in polyproteins that contained the NW X2-NTB site and the Lv protease. These results show that the ArMV-Lv protease has greater activity and is active on a greater range of cleavage sites than that of ArMV-NW.

Capturing hammerhead ribozyme structures in action by modulating general base catalysis.

We have obtained precatalytic (enzyme-substrate complex) and postcatalytic (enzyme-product complex) crystal structures of an active full-length hammerhead RNA that cleaves in the crystal. Using the natural satellite tobacco ringspot virus hammerhead RNA sequence, the self-cleavage reaction was modulated by substituting the general base of the ribozyme, G12, with A12, a purine variant with a much lower pKa that does not significantly perturb the ribozyme's atomic structure. The active, but slowly cleaving, ribozyme thus permitted isolation of enzyme-substrate and enzyme-product complexes without modifying the nucleophile or leaving group of the cleavage reaction, nor any other aspect of the substrate. The predissociation enzyme-product complex structure reveals RNA and metal ion interactions potentially relevant to transition-state stabilization that are absent in precatalytic structures.

RNA folding and the origins of catalytic activity in the hairpin ribozyme.

The nucleolytic ribozymes catalyse site-specific phosphodiester cleavage and ligation transesterification reactions in RNA. The hairpin ribozyme folds to generate an intimate loop-loop interaction to create the local environment in which catalysis can proceed. We have studied the ion-induced folding using single-molecule FRET experiments, showing that the four-way helical junction accelerates the folding 500-fold by introducing a discrete intermediate that juxtaposes the loops. Using FRET we can observe individual hairpin ribozyme molecules as they undergo multiple cycles of cleavage and ligation, and measure the rates of the internal reactions, free of uncertainties in the contributions of docking and substrate dissociation processes. On average, the cleaved ribozyme undergoes several docking-undocking events before a ligation reaction occurs. On the basis of these experiments, we have explored the role of the nucleobases G8 and A38 in the catalysis. Both cleavage and ligation reactions are pH dependent, corresponding to the titration of a group with pKa=6.2. We have used a novel ribonucleoside in which these bases are replaced by imidazole to investigate the role of acid-base catalysis in this ribozyme. We observe significant rates of cleavage and ligation, and a bell-shaped pH dependence for both.

Interaction in vitro between the proteinase of Tomato ringspot virus (genus Nepovirus) and the eukaryotic translation initiation factor iso4E from Arabidopsis thaliana.

Eukaryotic initiation factor eIF(iso)4E binds to the cap structure of mRNAs leading to assembly of the translation complex. This factor also interacts with the potyvirus VPg and this interaction has been correlated with virus infectivity. In this study, we show an interaction between eIF(iso)4E and the proteinase (Pro) of a nepovirus (Tomato ringspot virus; ToRSV) in vitro. The ToRSV VPg did not interact with eIF(iso)4E although its presence on the VPg-Pro precursor increased the binding affinity of Pro for the initiation factor. A major determinant of the interaction was mapped to the first 93 residues of Pro. Formation of the complex was inhibited by addition of m(7)GTP (a cap analogue), suggesting that Pro-containing molecules compete with cellular mRNAs for eIF(iso)4E binding. The possible implications of this interaction for translation and/or replication of the virus genome are discussed.

Expression and partial purification of recombinant tomato ringspot nepovirus 3C-like proteinase: comparison of the activity of the mature proteinase and the VPg-proteinase precursor.

The 3C-like proteinase (Pro) from Tomato ringspot virus (genus Nepovirus) is responsible for the processing of the RNA1-encoded (P1) and RNA2-encoded (P2) polyproteins. Cleavage between the VPg and Pro domains is inefficient in vitro and in E. coli, resulting in the accumulation of the VPg-Pro. In this study, we have compared the trans-activity of the Pro and VPg-Pro on various P1- and P2-derived precursors. Recombinant Pro and VPg-Pro were partially purified using an E. coli expression system. A mutation of the VPg-Pro cleavage site was introduced into the VPg-Pro to prevent slow release of the Pro. The Pro was five to ten times more active than the VPg-Pro on two P2 cleavage sites (at the N- and C-termini of the movement protein domain) and was approximately two times more active than the VPg-Pro on the third P2 cleavage site (between the X3 and X4 domains). Neither the Pro nor the VPg-Pro could cleave in trans P1-derived substrates containing the three cleavage sites delineating the X1, X2, putative NTP-binding protein and VPg domains. These results are discussed in light of the possible regulation of the proteinase activity during virus replication.

Genomic organization of RNA2 of Tomato ringspot virus: processing at a third cleavage site in the N-terminal region of the polyprotein in vitro.

The proteinase of Tomato ringspot virus (genus Nepovirus) is responsible for proteolytic cleavage of the RNA2-encoded polyprotein (P2) at two cleavage sites, allowing definition of the domains for the movement protein (MP) and coat protein. In this study, we have characterized a third cleavage site in the N-terminal region of P2 using an in vitro processing assay and partial cDNA clones. Results from site-directed mutagenesis of putative cleavage sites suggest that cleavage occurs at dipeptide Q(301)/G. Cleavage at this site is predicted to result in the release of two proteins from the N-terminal region of P2: a 34 kDa protein located at the N terminus of P2 (assuming translation initiation at the first AUG codon) and a 71 kDa protein located immediately upstream of the MP domain. In contrast, only one protein domain is present in the equivalent region of the P2 polyprotein of other characterized nepoviruses.

Importance of specific nucleotides in the folding of the natural form of the hairpin ribozyme.

The hairpin ribozyme in its natural context consists of two loops in RNA duplexes that are connected as arms of a four-way helical junction. Magnesium ions induce folding into the active conformation in which the two loops are in proximity. In this study, we have investigated nucleotides that are important to this folding process. We have analyzed the folding in terms of the cooperativity and apparent affinity for magnesium ions as a function of changes in base sequence and functional groups, using fluorescence resonance energy transfer. Our results suggest that the interaction between the loops is the sum of a number of component interactions. Some sequence variants such as A10U, G+1A, and C25U exhibit loss of cooperativity and reduced affinity of apparent magnesium ion binding. These variants are also very impaired in ribozyme cleavage activity. Nucleotides A10, G+1, and C25 thus appear to be essential in creating the conformational environment necessary for ion binding. The double variant G+1A/C25U exhibits a marked recovery of both folding and catalytic activity compared to either individual variant, consistent with the proposal of a triple-base interaction among A9, G+1, and C25 [Pinard, R., Lambert, D., Walter, N. G., Heckman, J. E., Major, F., and Burke, J. M. (1999) Biochemistry 38, 16035-16039]. However, substitution of A9 leads to relatively small changes in folding properties and cleavage activity, and the double variant G+1DAP/C25U (DAP is 2,6-diaminopurine), which could form an isosteric triple-base interaction, exhibits folding and cleavage activities that are both very impaired compared to those of the natural sequence. Our results indicate an important role for a Watson--Crick base pair between G+1 and C25; this may be buttressed by an interaction with A9, but the loss of this has less significant consequences for folding. 2'-Deoxyribose substitution leads to folding with reduced magnesium ion affinity in the following order: unmodified RNA > dA9 > dA10 > dC25 approximately dA10 plus dC25. The results are interpreted in terms of an interaction between the ribose ring of C25 and the ribose and base of A10, in agreement with the proposal of Ryder and Strobel [Ryder, S. P., and Strobel, S. A. (1999) J. Mol. Biol. 291, 295-311]. In general, there is a correlation between the ability to undergo ion-induced folding and the rate of ribozyme cleavage. An exception to this is provided by G8, for which substitution with uridine leads to severe impairment of cleavage but folding characteristics that are virtually unaltered from those of the natural species. This is consistent with a direct role for the nucleobase of G8 in the chemistry of cleavage.

Helical junctions as determinants for RNA folding: origin of tertiary structure stability of the hairpin ribozyme.

Helical junctions are ubiquitous structural elements that govern the folding and tertiary structure of RNAs. The tobacco ringspot virus hairpin ribozyme consists of two helix-loop-helix elements that lie on adjacent arms of a four-way junction. In the active form of the hairpin ribozyme, the loops are in proximity. The nature of the helical junction determines the stability of the hairpin ribozyme tertiary structure [Walter, N. G., Burke, J. M., and Millar, D. P. (1999) Nat. Struct. Biol. 6, 544-549] and thus its catalytic activity. We used two-, three-, and four-way junction hairpin ribozymes as model systems to investigate the thermodynamic basis for the different tertiary structure stabilities. The equilibrium between docked and extended conformers was analyzed as a function of temperature using time-resolved fluorescence resonance energy transfer (trFRET). As the secondary and tertiary structure transitions overlap, information from UV melting curves and trFRET had to be combined to gain insight into the thermodynamics of both structural transitions. It turned out that the higher tertiary structure stability observed in the context of a four-way junction is the result of a lower entropic cost for the docking process. In the two- and three-way junction ribozymes, a high entropic cost counteracts the favorable enthalpic term, rendering the docked conformer only marginally stable. Thus, two- and three-way junction tertiary structures are more sensitive toward regulation by ligands, whereas four-way junctions provide a stable scaffold. Altogether, RNA folding and stability appear to be governed by principles similar to those for the folding of proteins.

Structural basis for the guanosine requirement of the hairpin ribozyme.

To form a catalytically active complex, the essential nucleotides of the hairpin ribozyme, embedded within the internal loops of the two domains, must interact with one another. Little is known about the nature of these essential interdomain interactions. In the work presented here, we have used recent topographical constraints and other biochemical data in conjunction with molecular modeling (constraint-satisfaction program MC-SYM) to generate testable models of interdomain interactions. Visual analysis of the generated models has revealed a potential interdomain base pair between the conserved guanosine immediately downstream of the reactive phosphodiester (G(+1)) and C(25) within the large domain. We have tested this former model through activity assays, using all 16 combinations of bases at positions +1 and 25. When the standard ribozyme was used, catalytic activity was severely suppressed with substrates containing U(+1), C(+1), or A(+1). Similarly, mutations of the putative pairing partner (C(25) to A(25) or G(25)) reduce activity by several orders of magnitude. The U(25) substitution retains a significant level of activity, consistent with the possible formation of a G.U wobble pair. Strikingly, when combinations of Watson-Crick (or wobble) base pairs were introduced in these positions, catalytic activity was restored, strongly suggesting the existence of the proposed interaction. These results provide a structural basis for the guanosine requirement of this ribozyme and indicate that the hairpin ribozyme can now be engineered to cleave a wider range of RNA sequences.

Proteolytic processing of tomato ringspot nepovirus 3C-like protease precursors: definition of the domains for the VPg, protease and putative RNA-dependent RNA polymerase.

Tomato ringspot nepovirus (TomRSV) RNA-1 encodes a putative NTP-binding protein (NTB), a putative viral genome-linked protein (VPg), a putative RNA-dependent RNA polymerase (Pol) and a serine-like protease (Pro), which have been suggested to be involved in viral RNA replication. Proteolytic processing of protease precursors containing these proteins was studied in Escherichia coli and in vitro. The TomRSV protease could cleave the precursor proteins and release the predicted mature proteins or intermediate precursors. Although processing was detected at all three predicted cleavage sites (NTB-VPg, VPg-Pro and Pro-Pol), processing at the VPg-Pro cleavage site was inefficient, resulting in accumulation of the VPg-Pro intermediate precursor in E. coli and in vitro. In addition, the presence of the VPg sequence in the precursor resulted in increased cleavage at the Pro-Pol cleavage site in E. coli and in vitro. Direct N-terminal sequencing of the genomic RNA-linked VPg, of the mature protease purified from E. coli extracts and of radiolabelled mature polymerase purified from in vitro translation products revealed the sequences of the NTB-VPg, VPg-Pro and Pro-Pol dipeptide cleavage sites to be Q/S, Q/G and Q/S, respectively. In vitro processing at the NTB-VPg and Pro-Pol cleavage sites was not detected upon mutation or deletion of the conserved glutamine at the -1 position of the cleavage site. These results are discussed in light of the cleavage site specificity of the TomRSV protease.

Folding of the hairpin ribozyme in its natural conformation achieves close physical proximity of the loops.

The hairpin ribozyme is a self-cleaving motif found in the negatives strand of the satellite RNA of some plant viruses. In its natural context, the ribozyme comprises four helices, two of which contain conserved formally unpaired loops, that are adjacent arms of a four-way RNA junction. We show that the arms that would carry these loops are brought close together in the global conformation of the isolated junction. Using fluorescence resonance energy transfer, we demonstrate a two-magnesium ion-dependent conformational transition of the complete ribozyme that brings the loopbearing arms into close physical proximity. The ribozyme is active as a four-way junction, and the rate of cleavage may be modulated by the conformation of the four-way junction.

Tomato ringspot nepovirus protease: characterization and cleavage site specificity.

We have cloned the region of tomato ringspot nepovirus (TomRSV) RNA-1 coding for the putative TomRSV 3C-related protease (amino acids 1213 to 1508) in a transcription vector and in a transient expression vector. Using cell-free transcription and translation systems and plant protoplasts, we have demonstrated that proteins produced from these clones possess a proteolytic activity in trans on the cleavage site between the TomRSV movement and coat proteins. By amino acid homology of the TomRSV 3C-related protease with other nepo- and comovirus proteases, His1283, Glu1331 (or Asp1354) and Cys1433 have been predicted to constitute the catalytic triad. Site-directed mutagenesis of His1283 to Asp abolished the TomRSV protease activity, in vitro and in vivo. The cleavage site between the TomRSV movement and coat proteins has been determined to be Q/G, by direct protein sequencing. Previously, His1451 located in the substrate binding pocket of the TomRSV 3C-related protease has been suggested to be involved in the cleavage site specificity. We show that an inactive TomRSV 3C-related protease is obtained after substitution of His1451 with Leu. These results are discussed in light of the possible relation of the TomRSV 3C-related protease to 3C-related proteases of nepo-, como- and potyviruses.

Cis and trans reactions of hairpin ribozymes derived from the negative strand of arabis mosaic virus satellite RNA.

We have previously shown that the hairpin ribozyme-like structure of the negative strand of the satellite RNA of arabis mosaic virus [(- )sArMV] has indeed ribozyme activity. However, some mutagenesis analyses revealed surprisingly that the wild type ribozyme was less active than almost all the other mutant ribozymes tested. These results were derived from a trans-acting system. Here we tested this ribozyme activity in a cis-acting system. We show that the (-)s ArMV hairpin ribozyme has different target-site specificities between cis and trans cleavages. The wild type ribozyme has the highest self-cleaving activity among the ribozyme variants tested.

Construction of new hairpin ribozymes with replaced domains.

We have constructed a new type of hairpin ribozyme by cleaving and reverse-joining one of the two catalytic domains to conserve an essential bending structure. The two domains of the new ribozymes were tethered by different lengths of cytidylate linkers. These ribozymes retained the cleavage activity and the cleavage activities depended on the linker lengths. Although these rejoined ribozymes showed weak turnover abilities, those with 18 cytidylates showed a larger kcat/K(m) value than the natural hairpin ribozymes. These modifications in the primary structure of the hairpin ribozyme confirm the bent conformation for the catalytic reaction of this ribozyme, and provide a new approach for the design of highly efficient ribozymes.

Three-dimensional model of a hairpin ribozyme.

On the basis of the mutational and chemical-modification analysis, we propose the new secondary structure of a hairpin ribozyme, which contains three stems, a triple helix and the reverse Watson-Crick g+1C44 base pair at the 3' side of the cleavage site. The computational approach to the tertiary structure of a hairpin ribozyme have been carried out.

Differential proteolytic activities of precursor and mature forms of the 24K proteinase of grapevine fanleaf nepovirus.

The presence of a genome-linked protein (VPg) at the RNA 5'-end of the genome is a characteristic of different groups of animal and plant positive-sense single-stranded RNA viruses. These viruses express their structural and functional proteins from polyproteins that are sequentially processed by at least one viral proteinase. The grapevine fanleaf nepovirus 24K chymotrypsin-like cysteine proteinase, located between the VPg and the RNA polymerase in the RNA-1 encoded polyprotein P1, is active in its free form and in various precursors forms. The VPg proteinase precursor (VPg-Pro) constitutes a stable protein and its maturation in the reticulocyte lysate system occurs at a very low rate. Differences on cleavage activity were observed between the proteinase and its VPg-Pro precursor forms, depending upon the cleavage site considered. The proteinase alone has a greater cleavage efficiency than VPg-Pro at the Arg605/Gly606 and Cys257/Ala258 sites of polyprotein P2. On the other hand, the presumed Cys415/Ala416 site, present at the amino terminus of polyprotein P1, was preferentially cleaved by the VPg-Pro precursor. During their in vitro maturation, proteins containing the VPg proteinase-polymerase coding region or the proteinase-polymerase region were similar in their ability to cleave in cis between the proteinase and the RNA polymerase.