An eight-nucleotide sequence in the potato virus X 3' untranslated region is required for both host protein binding and viral multiplication.

Gel retardation and UV-cross-linking techniques were used to demonstrate that two tobacco proteins, with approximate molecular masses of 28 and 32 kDa, bind to a site within the 3' region of potato virus X (PVX) genomic RNA. The protein binding is specific, in that a 50-fold excess of unlabeled probe prevents formation of the complexes but no reduction is observed with a 2,000-fold molar excess of yeast tRNA. Complex formation is inhibited by poly(U) but is relatively unaffected by poly(A), poly(G), or poly(C-I). PVX RNA-host protein complex formation occurs in vitro at salt concentrations up to 400 mM. Deletion mapping indicates that the proteins bind within the 3' untranslated region (UTR) of PVX genomic RNA and that an 8-nucleotide U-rich sequence (5'-UAUUUUCU) is required for the binding. Deletion of the 8-nucleotide U-rich region from the 3' UTR of a sensitive PVX reporter virus that carries the luciferase gene in place of the PVX coat protein gene results in a more than 70,000-fold reduction in luciferase expression in tobacco protoplasts. RNA probes carrying the sequence GCGC in place of the central four contiguous uridines of the 8-nucleotide U-rich motif fail to bind host protein at detectable levels, and the same mutation, when introduced into the PVX reporter virus, eliminates viral multiplication. Mutations of 1 or 2 nucleotides within the same four uridines reduced both binding of host proteins and replication of reporter virus. These results indicate that the 8-nucleotide U-rich motif within the PVX 3' UTR is important for some aspect of viral multiplication and suggest that host protein binding plays a role in the process.     

Nucleotide sequence of the open reading frames adjacent to the coat protein cistron in potato virus X genome

The cloned cDNA copies corresponding to 1300 nucleotides adjacent to the 3'-terminal poly(A) tract of the potato virus X (PVX) genome have been sequenced. The amino acid sequences of three open reading frames were deduced from the nucleotide sequence. Two putative small nonstructural polypeptides corresponding to the open reading frames adjacent to the coat protein cistron possess some properties of membrane-associated proteins. Direct sequence homology and common structural peculiarities exist between the PVX small proteins and the putative small nonstructural proteins encoded by RNA 2 of hordeiviruses and furoviruses     

Complete Genome Sequence of a Chinese Isolate of Potato virus X and Analysis of Genetic Diversity

The complete genomic sequence of a Chinese Potato virus X isolate FX21 (PVX‐FX21) was determined from three overlapping cDNA clones. The genome of PVX‐FX21 is 6435 nucleotides in length excluding the poly(A) tail and contains five open reading frames (ORFs). Its entire genomic sequence shares 95.2–96.3% identities with Asian and European isolates, and 77.3–77.8% with American isolates. Phylogenetic analysis of the complete genomic sequence reveals two groups: the Eurasian group and the American group. PVX‐FX21 belongs to the Eurasian group and forms a separate sub‐branch with three Asian isolates. Similar analyses of the coat protein genes of 37 PVX isolates also reveal two major groups. All PVX isolates from Asia are clustered to group I, whereas isolates from Europe and America are clustered to both groups. Nucleotide sequence diversity analyses show that there is no geographical differentiation between PVX isolates and that constraint on the ORF encoding RNA‐dependent RNA polymerase is much higher than those on the other four ORFs.     

The 5' noncoding region of grapevine chrome mosaic nepovirus RNA-2 triggers a necrotic response on three Nicotiana spp

The 5' noncoding region (NCR) of grapevine chrome mosaic nepovirus (GCMV) was cloned in a viral vector derived from potato virus X (PVX). The recombinant virus obtained was inoculated to Nicotiana benthamiana, N. clevelandii, and N. tabacum plants. Infected plants developed necrotic symptoms in place of the vein clearing and mosaic typically observed after inoculation with PVX. Northern (RNA) blot analysis showed that the replication of PVX was not specifically altered by the presence of the GCMV 5' NCR. Inoculation of recombinant PVX harboring deleted forms of the GCMV 5' NCR showed that the three stem-loop structures at the 3' end of the 5' NCR (nucleotides 153 to 206) are dispensable for the induction of necrosis. Further deletion analysis indicated that neither the 5'-most 70 nucleotides of the 5' NCR nor the downstream region (nucleotides 71 to 217) alone is able to induce the necrotic symptoms. In the presence of both the sequence encoding the GCMV coat protein and the GCMV 3' NCR, the GCMV 5' NCR failed to induce necrosis in the PVX background. The mechanisms by which the expression of the 5' NCR might modify PVX symptoms are discussed.     

Complete genome sequence and analyses of the subgenomic RNAs of sweet potato chlorotic stunt virus reveal several new features for the genus Crinivirus

The complete nucleotide sequences of genomic RNA1 (9,407 nucleotides [nt]) and RNA2 (8,223 nt) of Sweet potato chlorotic stunt virus (SPCSV; genus Crinivirus, family Closteroviridae) were determined, revealing that SPCSV possesses the second largest identified positive-strand single-stranded RNA genome among plant viruses after Citrus tristeza virus. RNA1 contains two overlapping open reading frames (ORFs) that encode the replication module, consisting of the putative papain-like cysteine proteinase, methyltransferase, helicase, and polymerase domains. RNA2 contains the Closteroviridae hallmark gene array represented by a heat shock protein homologue (Hsp70h), a protein of 50 to 60 kDa depending on the virus, the major coat protein, and a divergent copy of the coat protein. This grouping resembles the genome organization of Lettuce infectious yellows virus (LIYV), the only other crinivirus for which the whole genomic sequence is available. However, in striking contrast to LIYV, the two genomic RNAs of SPCSV contained nearly identical 208-nt-long 3' terminal sequences, and the ORF for a putative small hydrophobic protein present in LIYV RNA2 was found at a novel position in SPCSV RNA1. Furthermore, unlike any other plant or animal virus, SPCSV carried an ORF for a putative RNase III-like protein (ORF2 on RNA1). Several subgenomic RNAs (sgRNAs) were detected in SPCSV-infected plants, indicating that the sgRNAs formed from RNA1 accumulated earlier in infection than those of RNA2. The 5' ends of seven sgRNAs were cloned and sequenced by an approach that provided compelling evidence that the sgRNAs are capped in infected plants, a novel finding for members of the Closteroviridae.     

Primary structure of the potato virus X genome: the region preceding the capsid protein cistron

DNA copies of the potato virus X (PVX) RNA corresponding to 2300 nucleotides at the 3'-end have been cloned. The cloned cDNA copies containing the nucleotides 445-1280 from the 3'-end have been sequenced. The 5'-terminal region of the PVX coat protein gene corresponds to residues 445-786 from the 3'-end. The amino acid sequences of two more open reading frames (ORF) have been deduced from the nucleotide sequence. The potential translation products of these ORF's would correspond to the nonstructural viral proteins. We have located the ORF1 within the region of residues 799-1009 preceding the coat protein cistron. The tentative protein is composed of 70 amino acids and has an aminoterminal segment which is markedly hydrophobic. ORF2 in the PVX sequence ends with UAG at nucleotides 942-944 and extends to the 5'-terminus for additional 340 nucleotides. The distant sequence homology exists between a carboxyterminal portion of PVX ORF2 and that of the nonstructural "30 K-proteins" of the plant tobamoviruses.     

Analysis of the genome structure of tobacco rattle virus strain PSG.

The sequence of the 3'-terminal 2077 nucleotides of genomic RNA 1 and the complete sequence of genomic RNA 2 of tobacco rattle virus (TRV, strain PSG) has been deduced. RNA 2 (1905 nucleotides) contains a single open reading frame for the viral coat protein (209 amino acids), flanked by 5'- and 3'-noncoding regions of 570 and 708 nucleotides, respectively. A subgenomic RNA (RNA 4) was found to lack the 5'-terminal 474 nucleotides of RNA 2 and is the putative messenger for coat protein. The deduced RNA 1 sequence contains the 3'-terminal part of a reading frame that probably corresponds to the TRV 170K protein and reading frames for a 29K protein and a 16K protein. Proteins encoded by the first two reading frames show significant amino acid sequence homology with corresponding proteins encoded by tobacco mosaic virus. Subgenomic RNAs 3 (1.6 kb) and 5 (0.7 kb) were identified as the putative messengers for the 29K and 16K proteins, respectively. At their 3'-termini all PSG-RNAs have an identical sequence of 497 nucleotides; at the 5'-termini homology is limited to 5 to 10 bases.     

Potato virus X: structure, disassembly and reconstitution

This paper summarizes some structural characteristics of Potato virus X (PVX), the flexuous filamentous plant potexvirus. A model of PVX coat protein (CP) tertiary structure in the virion proposed on the basis of tritium planigraphy combined with predictions of the protein tertiary structure is described. A possible role of glycosylation and phosphorylation in the CP structure and function is discussed. Two forms of PVX virion disassembly are discussed: (i) the virion co-translational disassembly after PVX CP in situ phosphorylation and (ii) disassembly of PVX triggered by different factors after linear destabilization of the virion by binding of the PVX-coded movement protein (TGBp1) to one end of the polar CP-helix. Special emphasis was placed on a translational activation of encapsidated PVX RNA and rapid disassembly of TGBp1-PVX complexes into free RNA and CP. The results of experiments on the PVX CP repolymerization and PVX reconstitution are considered. In particular, the products assembled from PVX RNA, CP and TGBp1 were examined. Single-tailed particles were found with a helical, head-like structure consisting of helically arranged CP subunits located at the 5'-tail of RNA; the TGBp1 was bound to the end of the head. Translatable 'RNA-CP-TGBp1' complexes may represent the transport form of the PVX infection.     

Complete genome sequence of garlic latent virus,a member of the carlavirus family

The complete genome sequence of the garlic latent virus (GLV) has been determined. The whole GLV genome consists of 8,353 nucleotides, excluding the 3'-end poly(A)+ tail, and contains six open-reading frames (ORFs). Putative proteins that were encoded by the reading frames contain the motifs that were conserved in carlavirus-specific RNA replicases, NTP-dependent DNA helicases, two viral membrane-bound proteins, a viral coat protein, and a zinc-finger. Overall, the GLV genome shows structural features that are common in carlaviruses. An in vitro translation analysis revealed that the zinc-finger protein is not produced as a transframe protein with the coat protein by ribosomal frameshifting. A Northern blot analysis showed that GLV-specific probes hybridized to garlic leaf RNA fragments of about 2.6 and 1.5 kb long, in addition to the 8.5 kb whole genome. The two subgenomic RNAs might be encapsidated into smaller viral particles. In garlic plants, 700 nm long flexuous rod-shaped virus particles were observed in the immunoelectron microscopy using polyclonal antibodies against the GLV coat proteins.     

Poly(C) sequence is located near the 5'-end of encephalomyocarditis virus RNA.

The distance between the poly(A) and poly(C) tracts in the molecules of encephalomyocarditis virus RNA has been estimated by two methods. The results indicate that these tracts are situated on the opposite ends of the viral RNA molecule. Evidence is presented that the poly(A) sequence in this molecule is located at the 3′-end. It is concluded that the poly(C) tract is situated at, or near, the 5′-end of the molecule.     

Crystallographic studies of RNA hairpins in complexes with recombinant MS2 capsids: implications for binding requirements.

The coat protein of bacteriophage MS2 is known to bind specifically to an RNA hairpin formed within the MS2 genome. Structurally this hairpin is built up by an RNA double helix interrupted by one unpaired nucleotide and closed by a four-nucleotide loop. We have performed crystallographic studies of complexes between MS2 coat protein capsids and four RNA hairpin variants in order to evaluate the minimal requirements for tight binding to the coat protein and to obtain more information about the three-dimensional structure of these hairpins. An RNA fragment including the four loop nucleotides and a two-base-pair stem but without the unpaired nucleotide is sufficient for binding to the coat protein shell under the conditions used in this study. In contrast, an RNA fragment containing a stem with the unpaired nucleotide but missing the loop nucleotides does not bind to the protein shell.     

Binding sites for type C viral phosphoprotein on the viral RNA genome

The distribution of binding sites for R-MuLV p12 phosphoprotein on the viral genome has been examined. Ribonucleoprotein complexes formed using 3′-poly A-containing viral RNA fragments of varying lengths and $\text{in vitro}$ radioiodinated p12 protein have been analyzed by sedimentation velocity and buoyant density gradients. Binding sites for 2–3 molecules of p12 protein can be detected within the first 400 nucleotides from the 3′-poly A segment. The possible presence of binding sites near the middle of the genome (～2500 nucleotides from the 3′-end) and very close to the 5′-terminus (within the terminal 100–200 nucleotides) is also indicated.     

Characterization of the Structure and Melting Behavior of the Loop I fragment of ColE1 RNA I

Abstract

We have synthesized two RNA fragments: a 42-mer corresponding to the full loop I sequence of the loop I region of ColE1 antisense RNA (RNA I), plus three additional Gs at the 5′-end, and a 31-mer which has 11 5′-end nucleotides (G(-2)-U9) deleted. The secondary structure of the 42-mer, deduced from one- and two-dimensional NMR spectra, consists of a stem of 11 base-pairs which contains a U-U base-pair and a bulged C base, a 7 nucleotide loop, and a single-stranded 5′ end of 12 nucleotides. The UV-melting study of the 42-mer further revealed a multi-step melting behavior with transition temperatures 32°C and 71°C clearly discernible. In conjunction with NMR melting study the major transition at 71°C is assigned to the overall melting of the stem region and the 32°C transition is assigned to the opening of the loop region. The deduced secondary structure agrees with that proposed for the intact RNA I and provides structural bases for understanding the specificity of RNase E.     

Interactions of Q beta replicase with Q beta RNA

The interactions of Qβ replicase with Qβ RNA were investigated by treating replicase-Qβ RNA complexes under various conditions with ribonuclease T₁, and by characterizing enzyme-bound RNA fragments recovered by a filter binding technique. Evidence for replicase binding at two internal regions of Qβ RNA was obtained. One region (at about 1250 to 1350 nucleotides from the 5′ end) overlaps with the initiation site for coat protein synthesis; this interaction is thought to be inessential for template activity but rather to be involved in the regulation of protein synthesis. Binding to this site (called the S-site) requires moderate concentrations of salt but no magnesium ions. The other region (at about 2550 to 2870 nucleotides from the 5′ end) is probably essential for template activity; binding to this site (called the M-site) is dependent on the presence of magnesium ions. The nucleotide sequences of the RNA fragments from the two sites were determined and found to have no common features. Under the conditions tested, replicase binding at the 3′ end of Qβ RNA could not be demonstrated, except when initiation of RNA synthesis was allowed to occur in the presence of GTP and host factor. If instead of intact Qβ RNA, a complete RNAase T₁ digest of Qβ RNA was allowed to bind to replicase, oligonucleotides from the S-site and the M-site, and oligonucleotides from a region close to the 3′ end, were found to have the highest affinity to the enzyme.The RNA fragments recovered in highest yield, M-2 and S-3 from the M and S-site, respectively, were isolated on a preparative scale and their enzyme binding properties were studied. In competition assays with random RNA fragments of the same size, selective binding was observed both for the M and the S-site fragment. Partial competition for replicase binding was found if M-2 and S-3 were presented simultaneously to the enzyme. Either fragment, if preincubated with replicase, caused a specific inhibition of initiation of Qβ RNA-directed RNA synthesis, without inhibiting the poly(rC)-directed reaction.The results are discussed in terms of a model of replicase-Qβ RNA recognition. Template specificity is attributed to binding of internal RNA regions to replicase, resulting in a specific spatial orientation of the RNA by which the inherently weak, but essential, interaction at the 3′ end is allowed to occur and to lead to the initiation of RNA synthesis.     

Analysis of the role of the coat protein N-terminal segment in Potato virus X virion stability and functional activity

Previously, we have reported that intact Potato virus X (PVX) virions cannot be translated in cell-free systems, but acquire this capacity by the binding of PVX-specific triple gene block protein 1 (TGBp1) or after phosphorylation of the exposed N-terminal segment of intravirus coat protein (CP) by protein kinases. With the help of in vitro mutagenesis, a nonphosphorylatable PVX mutant (denoted ST PVX) was prepared in which all 12 S and T residues in the 20-residue-long N-terminal CP segment were substituted by A or G. Contrary to expectations, ST PVX was infectious, produced normal progeny and was translated in vitro in the absence of any additional factors. We suggest that the N-terminal PVX CP segment somehow participates in virion assembly in vivo and that CP subunits in ST virions may differ in structure from those in the wild-type (UK3 strain). In the present work, to test this suggestion, we performed a comparative tritium planigraphy study of CP structure in UK3 and ST virions. It was found that the profile of tritium incorporation into ST mutant virions in some CP segments differed from that of normal UK3 virions and from UK3 complexed with the PVX movement protein TGBp1. It is proposed that amino acid substitutions in ST CP and the TGBp1-driven remodelling of UK3 virions induce structural alterations in intravirus CPs. These alterations affect the predicted RNA recognition motif of PVX CP, but in different ways: for ST PVX, labelling is increased in α-helices 6 and 7, whereas, in remodelled UK3, labelling is increased in the β-sheet strands β3, β4 and β5.