Virp1 is a host protein with a major role in Potato spindle tuber viroid infection in Nicotiana plants.

Viroids are small, circular, single-stranded RNA molecules that, while not coding for any protein, cause several plant diseases. Viroids rely for their infectious cycle on host proteins, most of which are likely to be involved in endogenous RNA-mediated phenomena. Therefore, characterization of host factors interacting with the viroid may contribute to the elucidation of RNA-related pathways of the hosts. Potato spindle tuber viroid (PSTVd) infects several members of the Solanaceae family. In an RNA ligand screening we have previously isolated the tomato protein Virp1 by its ability to specifically interact with PSTVd positive-strand RNA. Virp1 is a bromodomain-containing protein with an atypical RNA binding domain and a nuclear localization signal. Here we investigate the role of Virp1 in the viroid infection cycle by the use of transgenic lines of Nicotiana tabacum and Nicotiana benthamiana that either overexpress the tomato Virp1 RNA or suppress the orthologous Nicotiana genes through RNA silencing. Plants of the Virp1-suppressed lines were not infected by PSTVd or Citrus exocortis viroid through mechanical inoculation, indicating a major role of Virp1 in viroid infection. On the other hand, overexpression of tomato Virp1 in N. tabacum and N. benthamiana plants did not affect PSTVd KF 440-2 infectivity or symptomatology in these species. Transfection experiments with isolated protoplasts revealed that Virp1-suppressed cells were unable to sustain viroid replication, suggesting that resistance to viroid infection in Virp1-suppressed plants is likely the result of cell-autonomous events.

Short 5'-phosphorylated double-stranded RNAs induce RNA interference in Drosophila.

Double-stranded (ds) RNA causes the specific degradation of homologous RNAs in a process called "RNA interference (RNAi)"[1-4]; this process is called "posttranscriptional gene silencing (PTGS)" in plants [5-7]. Both classes of gene silencing have been reviewed extensively [8-13]. The duplex RNA becomes processed by Dicer [14] or another RNase III-like enzyme to short dsRNA fragments of about 21-23 nucleotides (nt) [15], which are incorporated in the RNA-induced silencing complex (RISC)[16] that directs target-specific RNA degradation [17, 18]. Here, we show that different synthetic dsRNA cassettes, consisting of two 5'-phosphorylated RNA strands of 22 nt each, can initiate RNAi in Drosophila embryos. The cassettes were active at similar quantities required to initiate RNAi by conventional dsRNA. Their sequence specificity was confirmed using synthetic dsRNA cassettes for two different genes, Notch and hedgehog; each time, only the relevant embryonic phenotype was observed. Introduction of point mutations had only a moderate effect on the silencing potential, indicating that the silencing machinery does not require perfect sequence identity. 5'-phosphorylated synthetic RNA was more active than its hydroxylated form. Substitution of either RNA strand by DNA strongly reduced activity. Synthetic cassettes of siRNA will provide a new tool to induce mutant phenotypes of genes with unknown function.

Replicating potato spindle tuber viroid RNA is accompanied by short RNA fragments that are characteristic of post-transcriptional gene silencing.

The low molecular weight fraction of tomato plants inoculated with potato spindle tuber viroid (PSTVd) contains a population of short PSTVd-specific RNAs of either polarity. The main constituents were RNAs of 22 and 23 nt representing different domains of the viroid genome. The occurrence of such distinct RNA species indicated that the nuclear replicating PSTVd RNA induces post-transcriptional gene silencing. The short RNAs were slightly more abundant at 30 days post-inoculation than at later stages and were present in plants infected with a mild, severe or lethal isolate of PSTVD: There was no apparent correlation between the quantity of small PSTVd-specific RNAs and the degree of virulence of the viroid isolate.

A novel RNA-binding protein from Triturus carnifex identified by RNA-ligand screening with the newt hammerhead ribozyme.

The newt hammerhead ribozyme is transcribed from Satellite 2 DNA, which consists of tandemly repeated units of 330 bp. However, different transcripts are synthesized in different tissues. In all somatic tissues and in testes, dimeric and multimeric RNA transcripts are generated which, to some extent, self-cleave into monomers at the hammerhead domain. In ovaries, primarily a distinct monomeric unit is formed by transcription, which retains an intact hammerhead self-cleavage site. The ovarian monomeric RNA associates to form a 12S complex with proteins that are poorly characterised so far. In this work we identified NORA, a protein that binds the ovarian form of the newt ribozyme. We show that the newt ribozyme binds to the Escherichia coli -expressed protein, as well as to a protein of identical size that is found exclusively in newt ovaries. Also NORA mRNA was detectable only in ovary, but in neither somatic tissues nor testes. The tissue-specific expression of NORA is analogous to the ovary-specific transcription of the newt ribozyme. Although NORA was identified by its ability to bind to the newt ribozyme in the presence of a vast excess of carrier RNA, it was able to interact with certain other RNA probes. This novel RNA-binding protein does not contain any motif characteristic for RNA-binding proteins or any other known protein domain, but it shares a striking similarity with a rat resiniferatoxin-binding protein.

Extracellular folate deaminase of Dictyostelium discoideum.

Folate deaminase released from cells of Dictyostelium discoideum is heterogeneous with respect to molecular weight and stability at 60 degrees C. The most heat-stable component isoelectrofocuses in a broad band at approx. pH 6. The Km value of this component for folate is approx. 7 x 10(-7)M and Mr approx. 40 000. The major portion if not all of the deaminase binds to immobilized concanavalin A and lentil lectin. Extracellular folate deaminase has a pH-optimum of approx. pH 6.0. This is higher than that of lysosomal enzymes, which are also glycoproteins released into the extracellular medium.

Structural requirements for viroid processing by RNase T1.

Viroids are replicated via a rolling circle-like mechanism in which (+) strand oligomeric intermediates have to be cleaved enzymatically to unit-length molecules followed by ligation to mature circles. A transcript of potato spindle tuber viroid, which is still infectious, consists of a monomeric molecule with only 22 additional nucleotides, thus doubling part of the central conserved region of viroids. It was shown that this transcript can be cleaved and ligated in vitro to circles by RNase T1. To elucidate the site and mechanism of processing, 16 different site-specific mutants of this longer-than-unit-length transcript were constructed and analyzed by in vitro processing with RNase T1, infectivity studies, temperature-gradient gel electrophoresis, and structure calculations. The wild-type sequence and several mutated transcripts are able to adopt a particular secondary structure which is the prerequisite for enzymatic cleavage and ligation by RNase T1. This "processing structure" exposes both potential cleavage sites in the nearest spatial neighborhood, thus favoring the subsequent ligation to circles. Those mutated sequences for which the formation of the processing structure is impossible or thermodynamically highly unfavored are not processed. The results demonstrate that the particular structural features of viroids enable them to be cleaved and ligated by one and the same enzyme, RNase T1. The in vitro mechanism may serve as a mechanistic model for cellular processing of viroids.

Catalytic antisense RNAs produced by incorporating ribozyme cassettes into cDNA.

A simple strategy is described for the generation of catalytic hammerhead-type ribozymes (Rz) that can be used as highly specific endoribonucleases to cleave a particular target RNA. The technique requires that a cloned cDNA fragment is available which encodes at least a part of the target RNA. About 25 different restriction recognition sequences can be utilized to incorporate specifically designed DNA cassettes into the cDNA. Besides some nucleotides which are specific for a certain restriction site, the DNA cassettes contain a sequence corresponding to the catalytic domain of the hammerhead Rz and, optionally, selectable marker genes, that are removable. The resulting recombinant DNA constructs permit the in vitro and in vivo synthesis of novel 'catalytic antisense RNAs' or 'antisense Rz (Az)', which combine two features: (i) they bind like antisense RNA to their specific substrate RNA, and (ii) they cleave their target as hammerhead Rz do. The utility of the strategy to generate Rz was demonstrated experimentally by incorporating a synthetic SalI-specific DNA ribozyme (Rz) cassette into a unique SalI site of a cloned cDNA fragment of plum pox virus (PPV), which is a single-stranded positive sense plant RNA virus, belonging to the group of potyviruses. The resulting Az constructs delivered Az that were directed against the PPV (+) or (-) RNA, respectively, which cleaved their corresponding target RNAs in the expected manner. Besides the synthetic Rz cassette, a comparable SalI-specific Rz cassette, that had been prepared from a specifically designed plasmid and that contained the tet gene inserted into the sequence of the catalytic domain of the Rz, was also incorporated into the SalI site of the PPV cDNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Episomal expression of a hammerhead ribozyme directed against plum pox virus.

Two related antisense RNAs directed against plum pox virus (PPV) were expressed episomally in Nicotiana clevelandii by infection with recombinant potato virus X (PVX). One recombinant PVX expressed an ordinary PPV antisense RNA of about 400 nucleotides, while the other expressed a related antisense RNA that carried the catalytic domain of a hammerhead ribozyme. Inoculation with the latter recombinant PVX resulted in the accumulation of ribozyme RNA that was catalytically active when tested in vitro with a PPV substrate RNA. Plants that had been inoculated with recombinant PVX viruses, expressing either PPV-directed antisense or ribozyme sequences or GUS RNA as a control, were challenged with PPV by a sequential second inoculation. In plants that expressed PPV antisense sequences, the appearance of PPV disease symptoms was delayed for 3-5 days. Quantification of PPV 1 week after inoculation showed that the protective effect by the episomally expressed catalytic antisense RNA was stronger than that of the ordinary antisense RNA. However, eventually all plants tested accumulated comparable titers of PPV.

A microscale procedure for isolating and sequencing the viroid RNA present in one gram of infected leaf tissue.

A microscale procedure for the isolation and purification of viroid RNA from one gram of viroid-infected leaf tissue and for its subsequent sequencing at the cDNA level is described using potato spindle tuber viroid (PSTV) as model system. Total nucleic acids are phenol-extracted and salt-fractionated with 2 M LiCl. The viroid-containing fraction is then subjected to bidirectional polyacrylamide gel electrophoresis. This removes all co-fractionated cellular RNAs from the circular viroid RNA which is finally recovered from the gel in pure form by isotachophoresis. Thus, from one gram of PSTV-infected tomato leaf tissue, about 100-250 ng of circular PSTV RNA can be obtained and used as template for several DNA primer-directed reverse transcription reactions. From the primer-extended overlapping cDNAs the entire sequence of the viroid progeny synthesized in an individual plant or plant leaf can thus be established by Maxam-Gilbert sequencing. This renders the procedure especially suited for the routine analysis of the in vivo fate of viroid mutants constructed in vitro.

Telomerase inhibitors.

Telomerase is attracting great interest as a target for anticancer research because telomerase activity is present in most malignant cells, but undetectable in most normal somatic cells. The antisense approach has been widely exploited and directed to telomerase RNA, chiefly the template region. Ribozymes have been less investigated. Agents that stabilize folded G-quadruplex structures also inhibit telomerase. Inhibitory agents from many chemical classes have been identified, many through screening, but their specificity of action is in doubt. A specific inhibitor is expected to immediately inhibit activity but not cell division, produce telomerase shortening over multiple generations, and ultimately produce end-to-end chromosomal fusion and growth arrest.

Molecular cloning of potato spindle tuber viroid (PSTV) cDNA synthesized by enzymatic elongation of PSTV-specific DNA primers: a general strategy for viroid cloning.

Different cDNAs were synthesized by primer extension from the RNA of the severe strain KF 440 of potato spindle tuber viroid (PSTV) with the aid of reverse transcriptase using three PSTV-specific DNA molecules as primers. The cDNAs were made double-stranded and cloned into plasmid pBR 322. Various overlapping subgenomic DNA fragments were prepared from these clones and recombined in two different ways. In both cases a PSTV DNA copy was obtained which represented the entire PSTV RNA genome. The sequence of the DNA of one of the resulting full-length clones was identical with the original PSTV isolate, whereas the other clone showed one nucleotide change. On the basis of these results the advantages and problems of different strategies for the molecular cloning of the circular viroid RNA genome are discussed.

Synthesis of (+) and (-) RNA molecules of potato spindle tuber viroid (PSTV) in isolated nuclei and its impairment by transcription inhibitors.

Transcription studies with highly purified potato cell nuclei in combination with a 'transcription-hybridization analysis' unequivocally demonstrate that the nucleus is the subcellular site where the entire process of PSTV replication takes place. Inhibition experiments with actinomycin D and alpha-amanitin furthermore suggest that the nuclear DNA-dependent RNA polymerases I and II are involved in the synthesis of PSTV (+) and (-) RNA, respectively.

Identification of a dicer homologue gene (DCL2) in Nicotiana tabacum.

Eukaryotes possess a mechanism that generates small interfering RNA (siRNA) and microRNA (miRNA) and use these to regulate gene expression at the transcriptional or post-transcriptional level. These small RNAs (21-24nt) are processed from long double-stranded RNA precursors by type III RNase enzymes, referred to as DICER or DICER-LIKE proteins (DCLs). In Arabidopsis, there are four DCL genes and their role in small RNA biogenesis and silencing has been the subject of intense study. DCL2 is less well studied than the other DCL proteins although it is known to play a role in formation of natural antisense siRNA and may be involved in transitive silencing of transgene transcripts. This study provides basic genomic information on DCL2 in the Nicotiana tabacum (NtDCL2) gene family and its probable roles in plant growth and development.

A helix 1-extended hairpin ribozyme exhibits altered cleavage behavior in vitro.

The catalytic domain of a hairpin ribozyme was incorporated at the 3'-end of a 254-base antisense RNA directed against the RNA of human immunodeficiency virus type 1 (HIV-1), generating a hairpin ribozyme with a largely extended helix 1. In parallel, a catalytic antisense RNA based on a hammerhead ribozyme was directed toward the same cleavage motif in the HIV-1 target. Both ribozymes were expected to create identical cleavage products. Cleavage analysis in vitro confirmed that the hammerhead ribozyme delivered the expected cleavage products. However, the helix 1-extended hairpin ribozyme catalyzed additional RNA cleavage at several unexpected sites, which were mapped. Some of the 3' cleavage products had other nucleotides than G at their 5'-terminus, indicating that the helix 1-extended hairpin ribozyme was able to cleave bonds other than NpG+1. Inspection of the sequence context of the different cleavage sites suggested that unconventional helices 2 in combination with an asymmetric loop A consisting of up to 32 unpaired nucleotides in the substrate strand were formed. A second variant of a helix 1-extended hairpin ribozyme that differed in two nucleotides gave consistent results.

Comparative analysis of cleavage rates after systematic permutation of the NUX consensus target motif for hammerhead ribozymes.

A trans-cleaving asymmetric hammerhead ribozyme directed against an AUC decreases target motif within an RNA specific for human immunodeficiency virus type 1 (HIV-1) was generated. The AUC decreases motif of the target RNA was permutated in order to generate all 12 variants of an NUX decreases consensus target motif, wherein N = A, C, G or U and X = A, C or U. Four asymmetric hammerhead ribozymes differing in the nucleotide that is complementary to N were generated, of which each was specific for three of the 12 target motifs. The residual sequence context within helices I and III remained unchanged. All 12 combinations resulted in cleavage of the target RNA. Using single-turnover conditions, the detectable cleavage rate constants at 37 degrees C were determined, which varied considerably depending on the NUX decreases motif. The NUC decreases motifs were cleaved more efficiently, with AUC decreases being cleaved best. Comparison with previous studies indicates that the sequence context of the NUX decreases motif plays a major role for the detectable cleavage activity.

Generation and application of asymmetric hammerhead ribozymes.

Most researchers who intend to suppress a particular gene are interested primarily in the application of ribozyme technology rather than its mechanistic details. This article provides some background information and describes a straightforward strategy to generate and test a special design of a ribozyme: the asymmetric hammerhead ribozyme. This version of a hammerhead ribozyme carries at its 5' end the catalytic domain and at its 3' end a relatively long antisense flank that is complementary to the target RNA. Asymmetric hammerhead ribozymes can be constructed via polymerase chain reaction amplification, and rules are provided on how to select the DNA oligonucleotides required for this reaction. In addition to details on construction, we describe how to test asymmetric hammerhead ribozymes for association with the target RNA in vitro, so that RNA constructs can be selected and optimized for fast hybridization with their target RNA. This test can allow one to minimize association problems caused by the secondary structure of the target RNA. Additionally, we describe the in vitro cleavage assay and the determination of the cleavage rate constant. Testing for efficient cleavage is also a prerequisite for reliable and successful application of the technology. A carefully selected RNA will be more promising when eventually used for target suppression in living cells.