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.

A New Ilarvirus Isolated from Grapevine in Greece.

In 1994, characteristic viruslike symptoms on grapevine were reported in the collection of the Grapevine Institute in Athens, Greece, on the hybrid Baresana × Baresana. The symptoms were sharp angular mosaic, leaf crinkle, and little leaf. The affected vines showed gradual decline and severe stunting or death. Such vines produced abortive flowers or very few berries with smaller, wrinkled, and nongerminating seeds. Serological testing, by enzyme-linked immunosorbent assay (ELISA), of the affected vines against the most common grapevine viruses Alfalfa mosaic, Arabis mosaic, Grapevine fanleaf, Grapevine fleck, Grapevine A, Rasberry ringspot, and grapevine leafroll-associated viruses gave negative results. A virus was isolated from affected grapevine young leaves by mechanical inoculation of Gomphrena globosa and single lesioned. The virus host range included G. globosa (local and systemic dark red or necrotic lesions), Chenopodium quinoa (necrotic local lesions and systemic mottle), and three tobacco cultivars (sharp necrotic local lesions, 1 to 3 mm in diameter). Pollination of C. quinoa with pollen from infected plant gave about 30% infected seedlings. The virus was purified from C. quinoa by differential centrifugation using 0.02 M phosphate buffer pH 8.0, containing 0.01 M DIECA and 0.01 M sodium thioglycolate as extraction buffers. In a purified preparation, quasisphaerical virus particles of about 29 nm were observed. Electrophoretic mobility of the viral coat protein showed a molecular weight of 30 kDa. Using purified preparations, an antiserum was obtained with a titer of 1:1024 in microprecipitin test and an optimum IgG dilution in ELISA of 1:10,000 for maximum absorption at OD405 nm Using degenerate primers designed from homologous regions in RNA-2 corresponding to a fragment of the polymerase gene of Ilarviruses, the expected 381-bp polymerase chain reaction product was obtained. This product was cloned and sequenced. Comparisons with sequence data from the homologous regions of RNA-2 of other known Ilarviruses, showed that the sequence of the above 381-bp amplicon shared 72% sequence similarity with Tobacco streak virus, 67% of Citrus variegation virus and Spinach latent virus, 66% of Asparagus virus 2 and Elm mottle virus, and 65% of Citrus leaf rugose virus. Based on the above data, it is concluded that the isolated virus is an Ilarvirus with closest similarity to Tobacco streak virus. From the relative bibliography (1-3) it appears that the virus reported here is different from Grapevine line pattern virus, a possible Ilarvirus, previously reported from Hungary. References: (1) J. Lehoczky et al. Kertgazdasag 19:61, 1987. (2) J. Lehoczky et al. Phytoparasitica 17:59, 1989. (3) J. Lehoczky et al. Phytopathol. Medit. 31:115, 1992.

Extension of helix II of an HIV-1-directed hammerhead ribozyme with long antisense flanks does not alter kinetic parameters in vitro but causes loss of the inhibitory potential in living cells.

When designed to cleave a target RNA in trans, the hammerhead ribozyme contains two antisense flanks which form helix I and helix III by pairing with the complementary target RNA. The sequences forming helix II are contained on the ribozyme strand and represent a major structural component of the hammerhead structure. In the case of an inhibitory 429 nucleotides long trans-ribozyme (2as-Rz12) which was directed against the 5'-leader/gag region of the human immunodeficiency virus type 1 (HIV-1), helix II was not pre-formed in the single-stranded molecule. Thus, major structural changes are necessary before cleavage can occur. To study whether pre-formation of helix II in the non-paired 2as-Rz12 RNA could influence the observed cleavage rate in vitro and its inhibitory activity on HIV-1 replication, we extended the 4 base pair helix II of 2as-Rz12 to 6, 10, 21, and 22 base pairs respectively. Limited RNase cleavage reactions performed in vitro at 37 degrees C and at physiological ion strength indicated that a helix II of the hammerhead domain was pre-formed when its length was at least six base pairs. This modification neither affected the association rate with target RNA nor the cleavage rate in vitro. In contrast to this, extension of helix II led to a significantly decreased inhibition of HIV-1 replication in human cells. Together with the finding of others that shortening of helix II to less than two base pairs reduces the catalytic activity in vitro, this observation indicates that the length of helix II in the naturally occurring RNAs with a hammerhead domain is already close or identical to the optimal length for catalytic activity in vitro and in vivo.

A three-nucleotide helix I is sufficient for full activity of a hammerhead ribozyme: advantages of an asymmetric design.

Trans-cleaving hammerhead ribozymes with long target-specific antisense sequences flanking the catalytic domain share some features with conventional antisense RNA and are therefore termed 'catalytic antisense RNAs'. Sequences 5' to the catalytic domain form helix I and sequences 3' to it form helix III when complexed with the target RNA. A catalytic antisense RNA of more than 400 nucleotides, and specific for the human immunodeficiency virus type 1 (HIV-1), was systematically truncated within the arm that constituted originally a helix I of 128 base pairs. The resulting ribozymes formed helices I of 13, 8, 5, 3, 2, 1 and 0 nucleotides, respectively, and a helix III of about 280 nucleotides. When their in vitro cleavage activity was compared with the original catalytic antisense RNA, it was found that a helix I of as little as three nucleotides was sufficient for full endonucleolytic activity. The catalytically active constructs inhibited HIV-1 replication about four-fold more effectively than the inactive ones when tested in human cells. A conventional hammerhead ribozyme having helices of just 8 nucleotides on either side failed to cleave the target RNA in vitro when tested under the conditions for catalytic antisense RNA. Cleavage activity could only be detected after heat-treatment of the ribozyme substrate mixture which indicates that hammerhead ribozymes with short arms do not associate as efficiently to the target RNA as catalytic antisense RNA. The requirement of just a three-nucleotide helix I allows simple PCR-based generation strategies for asymmetric hammerhead ribozymes. Advantages of an asymmetric design will be discussed.

Incorporation of the catalytic domain of a hammerhead ribozyme into antisense RNA enhances its inhibitory effect on the replication of human immunodeficiency virus type 1.

The catalytic domain of a hammerhead ribozyme was incorporated into a 413 nucleotides long antisense RNA directed against the 5'-leader/gag region of the human immunodeficiency virus type 1 (HIV-1) (pos. +222 to +634). The resulting catalytic antisense RNA was shown to cleave its target RNA in vitro specifically at physiological ion strength and temperature. We compared the antiviral effectiveness of this catalytic antisense RNA with that of the corresponding unmodified antisense RNA and with a mutated catalytic antisense RNA, which did not cleave the substrate RNA in vitro. Each of these RNAs was co-transfected into human SW480 cells together with infectious complete proviral HIV-1 DNA, followed by analysis of HIV-1 replication. The presence of the catalytically active domain resulted in 4 to 7 fold stronger inhibition of HIV-1 replication as compared to the parental antisense RNA and the inactive mutant. Kinetic and structural studies performed in vitro indicated that the ability for double strand formation was not changed in catalytic antisense RNA versus parental antisense RNA. Together, these data suggest that the ability to cleave target RNA is a crucial prerequisite for the observed increase of inhibition of the replication of HIV-1.

Processing of linear longer-than-unit-length potato spindle tuber viroid RNAs into infectious monomeric circular molecules by a G-specific endoribonuclease.

Different cDNA constructs were used for the in vitro synthesis of RNA transcripts that contain a complete monomeric unit of the potato spindle tuber viroid (PSTVd) plus an additional repeat of a part of the circular RNA genome. These permutated linear longer-than-unit-length PSTVd RNAs were incubated with the G-specific endoribonuclease RNase T1 which generated monomeric circular PSTVd RNA molecules that were infectious when mechanically inoculated to tomato plants. Besides the correct monomeric PSTVd RNA, smaller and larger circular RNAs were also formed during the reaction. The comparison of different transcripts revealed that correct in vitro processing of PSTVd RNA can proceed at alternative sites indicating that circularization is driven by RNA structure and not governed by a particular sequence. Based on these data, we propose a novel model for the processing of multimeric replicative viroid RNA intermediates through RNA cleavage and ligation catalyzed by a host endoribonuclease.