Complete replication in vitro of tobacco mosaic virus RNA by a template-dependent, membrane-bound RNA polymerase.

A crude membrane-bound RNA polymerase, obtained by differential centrifugation of extracts of tomato leaves infected with tobacco mosaic tobamovirus (tomato strain L) TMV-L), was purified by sucrose density gradient centrifugation. Removal of the endogenous RNA template with micrococcal nuclease rendered the polymerase template dependent and template specific. The polymerase was primer independent and able to initiate RNA synthesis on templates containing the 3'-terminal sequences of the TMV-L positive or negative strands. TMV-vulgare RNA was a less efficient template, while RNAs of cucumber mosaic cucumovirus and red clover necrotic mosaic dianthovirus, or 5'-terminal sequences of TMV-L positive or negative strands, did not act as templates for the polymerase. A main product of the reaction with TMV-L genomic RNA as a template, carried out in the presence of [alpha-32P]UTP, was genomic-length single-stranded RNA. This was shown to be the positive strand and uniformly labelled along its length, demonstrating complete replication of TMV-L RNA. Genomic-length double-stranded RNA, labelled in both strands, and small amounts of RNAs corresponding to the single- and double-stranded forms of the coat protein subgenomic mRNA were also formed. Antibodies to N-terminal and C-terminal portions of the 126-kDa protein detected the 126-kDa protein and the 183-kDa readthrough protein in purified RNA polymerase preparations, whereas antibodies to the readthrough portion of the 183-kDa protein detected only the 183-kDa protein. All three antibodies inhibited the template-dependent RNA polymerase, but none of them had any effect on the template-bound enzyme.     

Isolation and sequence of four small nuclear U RNA genes of Trypanosoma brucei subsp. brucei: identification of the U2, U4, and U6 RNA analogs.

Trypanosomes use trans splicing to place a common 39-nucleotide spliced-leader sequence on the 5' ends of all of their mRNAs. To identify likely participants in this reaction, we used antiserum directed against the characteristic U RNA 2,2,7-trimethylguanosine (TMG) cap to immunoprecipitate six candidate U RNAs from total trypanosome RNA. Genomic Southern analysis using oligonucleotide probes constructed from partial RNA sequence indicated that the four largest RNAs (A through D) are encoded by single-copy genes that are not closely linked to one another. We have cloned and sequenced these genes, mapped the 5' ends of the encoded RNAs, and identified three of the RNAs as the trypanosome U2, U4, and U6 analogs by virtue of their sequences and structural homologies with the corresponding metazoan U RNAs. The fourth RNA, RNA B (144 nucleotides), was not sufficiently similar to known U RNAs to allow us to propose an identify. Surprisingly, none of these U RNAs contained the consensus Sm antigen-binding site, a feature totally conserved among several classes of U RNAs, including U2 and U4. Similarly, the sequence of the U2 RNA region shown to be involved in pre-mRNA branchpoint recognition in yeast, and exactly conserved in metazoan U2 RNAs, was totally divergent in trypanosomes. Like all other U6 RNAs, trypanosome U6 did not contain a TMG cap and was immunoprecipitated from deproteinized RNA by anti-TMG antibody because of its association with the TMG-capped U4 RNA. These two RNAs contained extensive regions of sequence complementarity which phylogenetically support the secondary-structure model proposed by D. A. Brow and C. Guthrie (Nature [London] 334:213-218, 1988) for the organization of the analogous yeast U4-U6 complex.     

Nucleotide sequence of cucumber mosaic virus RNA. 1. Presence of a sequence complementary to part of the viral satellite RNA and homologies with other viral RNAs

The nucleotide sequence of the 3389 residues of RNA 1 (Mr 1.15 X 10(6) of the Q strain of cucumber mosaic virus (CMV) was determined, completing the primary structure of the CMV genome (8617 nucleotides). CMV RNA 1 was sequenced by the dideoxy-chain-termination method using M13 clones carrying RNA 1 sequences as well as synthetic oligonucleotide primers on RNA 1 as a template. At the 5' end of the RNA there are 97 noncoding residues between the cap structure and the first AUG (98-100), which is the start of a single long open-reading frame. This reading frame encodes a translation product of 991 amino acid residues (Mr 110791) and stops 319 nucleotide residues from the 3' end of RNA 1. In addition to the conserved 3' region present in all CMV RNAs (307 residues in RNA 1), RNAs 1 and 2 have highly homologous 5' leader sequences, a 12-nucleotide segment of which is also conserved in the corresponding RNAs of brome mosaic virus (BMV). CMV satellite RNA can form stable base pairs with a region of CMV RNAs 1 and 2 including this 12-nucleotide sequence, implying a regulatory function. This conserved sequence is part of a hairpin structure in RNAs 1 and 2 of CMV and BMV and in CMV satellite RNA. The entire translation products of RNA 1 of CMV and BMV could be aligned with significant homology. Less prominent homologies were found with alfalfa mosaic virus RNA 1 translation product and with tobacco mosaic virus Mr-126000 protein.     

Role of the 3′-Untranslated Regions of Alfalfa Mosaic Virus RNAs in the Formation of a Transiently Expressed Replicase in Plants and in the Assembly of Virions

Alfalfa mosaic virus (AMV) RNAs 1 and 2 encode the replicase proteins P1 and P2, respectively, whereas RNA 3 encodes the movement protein and the coat protein (CP). When RNAs 1 and 2 were transiently expressed from a T-DNA vector (R12 construct) by agroinfiltration of Nicotiana benthamiana, the infiltrated leaves accumulated minus-strand RNAs 1 and 2 and relatively small amounts of plus-strand RNAs. In addition, RNA-dependent RNA polymerase (RdRp) activity could be detected in extracts of the infiltrated leaves. After transient expression of RNAs 1 and 2 with the 3'-untranslated regions (UTRs) of both RNAs deleted (R1Delta/2Delta construct), no replication of RNAs 1 and 2 was observed, while the infiltrated leaves supported replication of RNA 3 after inoculation of the leaves with RNA 3 or expression of RNA 3 from a T-DNA vector (R3 construct). No RdRp activity could be isolated from leaves infiltrated with the R1Delta/2Delta construct, although P1 and P2 sedimented in a region of a glycerol gradient where active RdRp was found in plants infiltrated with R12. RdRp activity could be isolated from leaves infiltrated with constructs R1Delta/2 (3'-UTR of RNA 1 deleted), R1/2Delta (3'-UTR of RNA 2 deleted), or R1Delta/2Delta plus R3. This demonstrates that the 3'-UTR of AMV RNAs is required for the formation of a complex with in vitro enzyme activity. RNAs 1 and 2 with the 3'-UTRs deleted were encapsidated into virions by CP expressed from RNA 3. This shows that the high-affinity binding site for CP at the 3'-termini of AMV RNAs is not required for assembly of virus particles.     

Generation and analysis of nonhomologous RNA-RNA recombinants in brome mosaic virus: sequence complementarities at crossover sites.

All three single-stranded RNAs of the brome mosaic virus (BMV) genome contain a highly conserved, 193-base 3' noncoding region. To study the recombination between individual BMV RNA components, barley plants were infected with a mixture of in vitro-transcribed wild-type BMV RNAs 1 and 2 and an RNA3 mutant that carried a deletion near the 3' end. This generated a population of both homologous and nonhomologous 3' recombinant BMV RNA3 variants. Sequencing revealed that these recombinants were derived by either single or double crossovers with BMV RNA1 or RNA2. The primary sequences at recombinant junctions did not show any similarity. However, they could be aligned to form double-stranded heteroduplexes. This suggested that local hybridizations among BMV RNAs may support intermolecular exchanges.     

Three helical domains form a protein binding site in the 5S RNA-protein complex from eukaryotic ribosomes.

A ribosomal protein binding site in the eukaryotic 5S rRNA has been delineated by examining the effect of sequence variation and nucleotide modification on the RNA's ability to exchange into the EDTA-released, yeast ribosomal 5S RNA-protein complex. 5S RNAs of divergent sequence from a variety of eukaryotic origins could be readily exchanged into the yeast complex but RNA from bacterial origins was rejected. Nucleotide modifications in any of three analogous helical regions in eukaryotic 5S RNAs of differing origin reduced the ability of this RNA molecule to form homologous or heterologous RNA-protein complexes. Because sequence comparisons did not indicate common nucleotide sequences in the interacting helical regions, a model is suggested in which the eukaryotic 5S RNA binding protein does not simply recognize specific nucleotide sequences but interacts with three strategically oriented helical domains or functional groups within these domains. Two of the domains bear a limited sequence homology with each other and contain an unpaired nucleotide or "bulge" similar to that recently reported for one of the 5S RNA binding proteins in Escherichia coli (Peattie, D.A., Douthwaite, S., Garrett, R.A. and Noller, H.F. (1981) Proc. Natl. Acad. Sci. 78, 7331-7335). The results further indicate that the single ribosomal protein of eukaryotic 5S RNA-protein complexes interacts with the same region of the 5S rRNA molecule as do the multiple protein components in complexes of prokaryotic origin.     

Minus-strand initiation by brome mosaic virus replicase within the 3' tRNA-like structure of native and modified RNA templates

An RNA-dependent RNA polymerase (replicase) extract from brome mosaic virus-infected barley leaves has been shown to initiate synthesis of (-) sense RNA from (+) sense virion RNA. Initiation occurred de novo, as demonstrated by the incorporation of [gamma-32P]GTP into the product. Sequencing using cordycepin triphosphate to terminate (-) strands during their synthesis by the replicase generated sequence ladders that confirmed that copying was accurate, and that initiation occurred very close to the 3' end. The precise site of initiation was further defined by testing the replicase template activity after stepwise removal of 3'-terminal nucleotides. Whereas removal of the terminal A did not decrease template activity, removal of the next nucleotide (C-2) did. Thus, initiation almost certainly occurs opposite the penultimate 3'-nucleotide (C-2) in vitro. The structure of the double-stranded replicative form of RNA isolated from brome mosaic virus-infected leaves was consistent with such a mechanism occurring in vivo, in that it lacked the 3'-terminal A found on virion RNAs. The specific site of (-) strand initiation and normal template activity were retained for RNAs with as many as 15 to 30 A residues added to the 3' end. However, only limited oligonucleotide 3' extensions can be present on active templates. In order to assess the 5' extent of sequences required for an active template, a 134-nucleotide-long fragment of brome mosaic virus RNA, corresponding to the tRNA-like structure, was generated. This RNA had high template activity, but a shorter 3' (85-nucleotide) fragment was inactive. RNAs with various heterologous sequences 5' to position 134 also showed high template activity. Thus, the 3'-terminal tRNA-like structure common to all four brome mosaic virus virion RNAs contains all of the signals required for initiation of replication, and sequences 5' to it do not play a role in template selection.     

Effects of amino-acid substitutions in the Brome mosaic virus capsid protein on RNA encapsidation

Brome mosaic virus (BMV) packages its genomic RNAs (RNA1, RNA2, and RNA3) and subgenomic RNA4 into three different particles. However, since the RNAs in the virions have distinct lengths and electrostatic charges, we hypothesize that subsets of the virions should have distinct properties. A glutamine to cysteine substitution at position 120 of the capsid protein (CP) was found to result in a mutant virus named QC that exhibited a dramatically altered ratio of the RNAs in virions. RNA2 was far more abundant than the other RNAs, although the ratios could be affected by the host plant species. RNAs with the QC mutation were competent for replication early in the infection, suggesting that they were either selectively packaged or degraded after packaging. In support of the latter idea, low concentrations of truncated RNA1 that co-migrated with RNA2 were found in the QC virions. Spectroscopic analysis and peptide fingerprinting experiments showed that the QC virus capsid interacted with the encapsidated RNAs differently than did the wild type. Furthermore, wild-type BMV RNA1 was found to be more susceptible to nuclease digestion relative to RNA2 as a function of the buffer pH. Other BMV capsid mutants also had altered ratios of packaged RNAs.     

Morpholino spin-labeling for base-pair sequencing of a 3'-terminal RNA stem by proton homonuclear Overhauser enhancements: yeast ribosomal 5S RNA

Base-pair sequences for 5S and 5.8S RNAs are not readily extracted from proton homonuclear nuclear Overhauser enhancement (NOE) connectivity experiments alone, due to extensive peak overlap in the downfield (11-15 ppm) proton NMR spectrum. In this paper, we introduce a new method for base-pair proton peak assignment for ribosomal RNAs, based upon the distance-dependent broadening of the resonances of base-pair protons spatially proximal to a paramagnetic group. Introduction of a nitroxide spin-label covalently attached to the 3'-terminal ribose provides an unequivocal starting point for base-pair hydrogen-bond proton NMR assignment. Subsequent NOE connectivities then establish the base-pair sequence for the terminal stem of a 5S RNA. Periodate oxidation of yeast 5S RNA, followed by reaction with 4-amino-2,2,6,6-tetramethylpiperidinyl-1-oxy (TEMPO-NH2) and sodium borohydride reduction, produces yeast 5S RNA specifically labeled with a paramagnetic nitroxide group at the 3'-terminal ribose. Comparison of the 500-MHz 1H NMR spectra of native and 3'-terminal spin-labeled yeast 5S RNA serves to identify the terminal base pair (G1 . C120) and its adjacent base pair (G2 . U119) on the basis of their proximity to the 3'-terminal spin-label. From that starting point, we have then identified (G . C, A . U, or G . U) and sequenced eight of the nine base pairs in the terminal helix via primary and secondary NOE's.     

A chimeric satellite transgene sequence is inefficiently targeted by viroid-induced DNA methylation in tobacco

In plants, transgenes containing Potato spindle tuber viroid (PSTVd) cDNA sequences were efficient targets of PSTVd infection-mediated RNA-directed DNA methylation. Here, we demonstrate that in PSTVd-infected tobacco plants, a 134 bp PSTVd fragment (PSTVd-134) did not become densely methylated when it was inserted into a chimeric Satellite tobacco mosaic virus (STMV) construct. Only about 4–5% of all cytosines (Cs) of the PSTVd-134 were methylated when flanked by satellite sequences. In the same plants, C methylation was approximately 92% when the PSTVd-134 was in a PSTVd full length sequence context and roughly 33% when flanked at its 3′ end by a 19 bp PSTVd and at its 5′ end by a short viroid-unrelated sequence. In addition, PSTVd small interfering RNAs (siRNAs) produced from the replicating viroid failed to target PSTVd-134-containing chimeric STMV RNA for degradation. Satellite RNAs appear to have adopted secondary structures that protect them against RNA interference (RNAi)—mediated degradation. Protection can be extended to short non-satellite sequences residing in satellite RNAs, rendering them poor targets for nuclear and cytoplasmic RNAi induced in trans.     

Properties of Single- and Double-stranded Ribonucleic Acid from Barley Plants Infected with Bromegrass Mosaic Virus

Incorporation of ³²P into nucleic acids in barley plants infected with bromegrass mosaic virus (BMV) was analyzed by chromatography on methylated albumin kieselguhr (MAK) columns. Treatment with actinomycin D reduced the synthesis of ribosomal ribonucleic acid (RNA) to low levels and allowed the detection of the three components of BMV-RNA in vivo. The kinetic study on ³²P incorporation into these BMV-RNA components suggested that a single cleavage occurred in some of the intact RNA shortly after completion of its synthesis, giving rise to the small and medium components. Chromatographic analyses also revealed a double-stranded, ribonuclease-resistant RNA which has been purified by differential extraction, sucrose-density gradient centrifugation, and MAK column chromatography. This RNA sediments at approximately 14S, is alkali-labile, and has a sharp thermal transition with a T_m of 96 C in 0.1 × standard saline citrate buffer, as determined by susceptibility to ribonuclease. The RNA is absent in uninfected barley plants.     

Functional equivalence of common and unique sequences in the 3' untranslated regions of alfalfa mosaic virus RNAs 1, 2, and 3.

The 3' untranslated regions (UTRs) of alfalfa mosaic virus (AMV) RNAs 1, 2, and 3 consist of a common 3'-terminal sequence of 145 nucleotides (nt) and upstream sequences of 18 to 34 nt that are unique for each RNA. The common sequence can be folded into five stem-loop structures, A to E, despite the occurrence of 22 nt differences between the three RNAs in this region. Exchange of the common sequences or full-length UTRs between the three genomic RNAs did not affect the replication of these RNAs in vivo, indicating that the UTRs are functionally equivalent. Mutations that disturbed base pairing in the stem of hairpin E reduced or abolished RNA replication, whereas compensating mutations restored RNA replication. In vitro, the 3' UTRs of the three RNAs were recognized with similar efficiencies by the AMV RNA-dependent RNA polymerase (RdRp). A deletion analysis of template RNAs indicated that a 3'-terminal sequence of 127 nt in each of the three AMV RNAs was not sufficient for recognition by the RdRp. Previously, it has been shown that this 127-nt sequence is sufficient for coat protein binding. Apparently, sequences required for recognition of AMV RNAs by the RdRp are longer than sequences required for CP binding.     

Exploration of RNA 3' terminal locations in rat ribosome.

The locations of the 3' ends of RNAs in rat ribosome were studied by a fluorescence-labeling method combined with high hydrostatic pressure and agarose electrophoresis. Under physiological conditions, only the 3' ends of 28 S and 5.8 S RNA in 80 S ribosome could be labeled with a high sensitive fluorescent probe - fluorescein 5-thiosemicarbazide (FTSC), indicating that the 3' termini of 28 S and 5.8 S RNA were located on or near the surface of 80 S ribosome. The 3' terminus of 5 S RNA could be attacked by FTSC only in the case of the dissociation of the 80 S ribosome into two subunits induced by high salt concentration (1 M KCl) or at high hydrostatic pressure, showing that the 3' end of 5 S RNA was located on the interface of two subunits. However, no fluorescence-labeled 18 S RNA could be detected under all the conditions studied, suggesting that the 3' end of 18 S RNA was either located deeply inside ribosome or on the surface but protected by proteins. It was interesting to note that modifications of the 3' ends of ribosomal RNAs including oxidation with NaIO4, reduction with KBH4 and labeling with fluorescent probe did not destroy the translation activity of ribosome, indicating that the 3' ends of RNAs were not involved in the translation activity of ribosome.     

Nature and specificity of the RNA-protein interaction in the case of the tymoviruses.

Dissociation-reassociation experiments performed with turnip yellow mosaic virus in the presence of various RNAs and polynucleotides were used to investigate the degree of specificity and the contribution of the associated RNA moiety to the stability of TYMV. The results emphasize the importance of strategic cytosine residues spread along the RNA chain. Some insight into the contribution of the protein could be gained from comparison of TYMV and eggplant mosaic virus (EMV), a virus similar to TYMV although its top component contains low molecular mass RNA's able to bind various amino acids. Hydrophobic interactions between protein subunits are less important in EMV than in TYMV, and artificial capsids could be obtained from dissociated EMV coat protein. Whether the capsid is or is not the precursor of the virion in tymovirus morphogenesis is discussed.     

Multi-enzymatic glucosylation using Eucalyptus UDP-glucosyltransferase coupled UDPglucose-fermentation by bakers' yeast.

The enzymatic synthesis of glucoside compounds using a membrane-associated UDP-glucosyltransferase fraction from Eucalyptus perriniana cultured cells as a water-insoluble catalyst (N. Nakajima, et. al., J. Ferment. Bioeng., 84 (5), pp. 455-460, 1997) has been effectively done by coupling UDPglucose-fermentation by bakers' yeast. For example, beta-thujaplicin (hinokitiol) and p-aminobenzoic acid were converted respectively to their corresponding beta-D-monoglucosides with the conversion rate of around 24-26% by the multi-enzymatic system with UDPglucose as a glucose donor, which is produced by yeast cells from glucose and 5'-UMP. Addition of either cellobiose, a substrate of beta-glucosidase, or DL-1,2-anhydro-myo-inositol, an inhibitor for the enzyme in the reaction mixture, could increased the yield of these beta-D-monoglucosides. This new enzymatic system could also be used for the synthesis of flavonoid glucosides such as isoquercitrin (quercetin 3-O-beta-D-glucoside).     

Biological activities of hybrid RNAs generated by 3''-end exchanges between tobacco mosaic and brome mosaic viruses.

Sequences within the conserved, aminoacylatable 3' noncoding regions of brome mosaic virus (BMV) genomic RNAs 1, 2, and 3 direct initiation of negative-strand synthesis by BMV polymerase extracts and, like sequences at the structurally divergent but aminoacylatable 3' end of tobacco mosaic virus (TMV) RNA, are required in cis for RNA replication in vivo. A series of chimeric RNAs in which selected 3' segments were exchanged between the tyrosine-accepting BMV and histidine-accepting TMV RNAs were constructed and their amplification was examined in protoplasts inoculated with or without other BMV and TMV RNAs. TMV derivatives whose 3' noncoding region was replaced by sequences from BMV RNA3 were independently replication competent when the genes for the TMV 130,000-M(r) and 180,000-M(r) replication factors remained intact. TMV replicase can thus utilize the BMV-derived 3' end, though at lower efficiency than the wild-type (wt) TMV 3' end. Providing functional BMV RNA replicase by coinoculation with BMV genomic RNAs 1 and 2 did not improve the amplification of these hybrid genomic RNAs. By contrast, BMV RNA3 derivatives carrying the 3' noncoding region of TMV were not amplified when coinoculated with wt BMV RNA1 and RNA2, wt TMV RNA, or all three. Thus, BMV replicase appeared to be unable to utilize the TMV 3' end, and there was no evidence of intervirus complementation in the replication of any of the hybrid RNAs. In protoplasts coinoculated with BMV RNA1 and RNA2, the nonamplifiable RNA3 derivatives bearing TMV 3' sequences gave rise to diverse new rearranged or recombined RNA species that were amplifiable.