Thermodynamic analysis of conserved loop-stem interactions in P1-P2 frameshifting RNA pseudoknots from plant Luteoviridae

The RNA genomes of plant luteovirids beet western yellows virus (BWYV), potato leaf roll virus (PLRV), and pea enation mosaic virus (PEMV RNA1; PEMV-1) contain a short mRNA pseudoknotted motif overlapping the P1 and P2 open reading frames required for programmed -1 mRNA ribosomal frameshifting. The relationship between structure, stability, and function is poorly understood in these RNA systems. A m(5)-C(8)-substituted BWYV RNA is employed to establish that the BWYV P1-P2 pseudoknot is protonated at cytidine 8 in loop L1 (delta(N(3)H)+ = 12.98 ppm), which stabilizes a C(+.)(G-C) major groove base triple by Delta(DeltaG(37))(protonation) = 3.1 (+/-0.4) kcal mol(-1). The stabilities of both the PLRV and PEMV-1 P1-P2 pseudoknots are also strongly pH-dependent, with Delta(DeltaG(37))(protonation) = 2.1 (+/-0.2) kcal mol(-1) for the PEMV-1 pseudoknot despite a distinct structural context. As previously found for the BWYV pseudoknot [Nixon and Giedroc (2000) J. Mol. Biol. 296, 659], both the PLRV and PEMV-1 RNAs are stabilized by DeltaH > or = 30 kcal mol(-)(1) in excess of secondary structure predictions, attributed to loop L2-stem S1 minor groove triplex interactions. BWYV RNAs containing single 2'-deoxy or A --> G substitutions that disrupt L2-S1 hydrogen bonding are strongly destabilized with Delta(DeltaG(37))(folding) (pH = 7.0) ranging from approximately 1.8 (+/-0.3) to > or =4.0 kcal mol(-1), relative to the wild-type BWYV RNA. These findings suggest that each member of this family of pseudoknots adopts a tightly folded structure that maximizes the cooperativity and complementarity of L1-S2 and L2-S1 loop-stem interactions required in part to offset the low intrinsic stability of the short three base pair pseudoknot stem S2.     

Quantitative studies on the uptake and retention of potato leafroll virus by aphids in laboratory and field conditions

Enzyme-linked immunosorbent assay (ELISA) was adapted for the efficient detection and assay of potato leafroll virus (PLRV) in aphids. Best results were obtained when aphids were extracted in 0.05 M phosphate buffer, pH 7.0, and the extracts incubated at 37 °C for 1 h before starting the assay. Using batches of 20 green peach aphids (Myzus persicae), about 0.01 ng PLRV/aphid could be detected. The virus could also be detected in single aphids allowed a 1-day acquisition access period on infected potato leaves. The PLRV content of aphids depended on the age of potato source-plants and the position of source leaves on them. It increased with increase in acquisition access period up to 7 days but differed considerably between individual aphids. A maximum of 7 ng PLRV/aphid was recorded but aphids more usually accumulated about 0.2 ng PLRV per day. When aphids were allowed acquisition access periods of 1–3 days, and then caged singly on Physalis floridana seedlings for 3 days, the PLRV content of each aphid, measured subsequently, was not strongly correlated with the infection of P. floridana. The concentration of PLRV in leaf extracts differed only slightly when potato plants were kept at 15, 20, 25 or 30 °C for 1 or 2 wk, but the virus content of aphids kept on leaves at the different temperatures decreased with increase of temperature. PLRV was transmitted readily to P. floridana at all temperatures, but by a slightly smaller proportion of aphids, and after a longer latent period, at 15 °C than at 30 °C. The PLRV content of M. persicae fed on infected potato leaves decreased with increasing time after transfer to turnip (immune to PLRV). The decrease occurred in two phases, the first rapid and the second very slow. In the first phase the decrease was faster, briefer and greater at 25 and 30 °C than at 15 and 20 °C. No evidence was obtained that PLRV multiplies in M. persicae. These results are compatible with a model in which much of the PLRV in aphids during the second phase is in the haemocoele, and transmission is mainly limited by the rate of passage of virus particles from haemolymph to saliva. The potato aphid, Macrosiphum euphorbiae, transmitted PLRV much less efficiently than M. persicae. Its inefficiency as a vector could not be ascribed to failure to acquire or retain PLRV, or to the degradation of virus particles in the aphid. Probably only few PLRV particles pass from the haemolymph to saliva in this species. The virus content of M. euphorbiae collected from PLRV-infected potato plants in the field increased from early June to early July, and then decreased. PLRV was detected both in spring migrants collected from the plants and in summer migrants caught in yellow water-traps. PLRV was also detected in M. persicae collected from infected plants in July and August, and in trapped summer migrants, but their PLRV content was less than that of M. euphorbiae, and in some instances was too small for unequivocal detection.     

Immunocytology Shows the Presence of Tobacco Etch Virus P3 Protein in Nuclear Inclusions

Intracellular localization studies of various potyvirus proteins have been made in hope of finding clues to their function(s). Immunocytological studies localized many of the tobacco etch virus (TEV)-encoded proteins in infected cells. We used antiserum against the nonstructural P3 protein of TEV to determine the subcellular location of the P3 protein in ultrathin sections of virus-infected cells. Immunogold labeling with the antiserum showed labels associated with nucleoli, nuclei, or NIs. Absorption of antiserum with purified NIs or P3 protein resulted in no labeling. TEV NIs are known to contain a bifunctional genome-linked protein–viral proteinase (NIa–VPg) and RNA-dependent RNA polymerase (NIb). It appeared that the TEV P3 protein was a third nonstructural viral protein of NIs of TEV if the NIa–VPg is considered one protein. The presence of P3 in NIs was also supported by Western blot assays. P3 protein in the nucleolus and nucleus could indicate that it, too, is involved in early stages of viral replication.     

Interaction of Sesbania mosaic virus movement protein with VPg and P10: implication to specificity of genome recognition

Sesbania mosaic virus (SeMV) is a single strand positive-sense RNA plant virus that belongs to the genus Sobemovirus. The mechanism of cell-to-cell movement in sobemoviruses has not been well studied. With a view to identify the viral encoded ancillary proteins of SeMV that may assist in cell-to-cell movement of the virus, all the proteins encoded by SeMV genome were cloned into yeast Matchmaker system 3 and interaction studies were performed. Two proteins namely, viral protein genome linked (VPg) and a 10-kDa protein (P10) c v gft encoded by OFR 2a, were identified as possible interacting partners in addition to the viral coat protein (CP). Further characterization of these interactions revealed that the movement protein (MP) recognizes cognate RNA through interaction with VPg, which is covalently linked to the 5' end of the RNA. Analysis of the deletion mutants delineated the domains of MP involved in the interaction with VPg and P10. This study implicates for the first time that VPg might play an important role in specific recognition of viral genome by MP in SeMV and shed light on the possible role of P10 in the viral movement.     

Identification of Human Astrovirus Genome-Linked Protein (VPg) Essential for Virus Infectivity

Viral genome-linked proteins (VPgs) have been identified in several single-stranded positive-sense RNA virus families. The presence of such protein in the family Astroviridae has not been fully elucidated, although a putative VPg coding region in open reading frame 1a (ORF1a) of astrovirus with high amino acid sequence similarity to the VPg coding region of Caliciviridae has been previously identified. In this work we present several experimental findings that show that human astrovirus (HAstV) RNA encodes a VPg essential for viral infectivity: (i) RNase treatment of RNA purified from astrovirus-infected cells results in a single protein of 13 to 15 kDa, compatible with the predicted astrovirus VPg size; (ii) the antibody used to detect this 13- to 15-kDa protein is specifically directed against a region that includes the putative VPg coding region; (iii) the 13- to 15-kDa protein detected has been partially sequenced and the sequence obtained is contained in the computationally predicted VPg; (iv) the protein resulting from this putative VPg coding region is a highly disordered protein, resembling the VPg of sobemo-, calici- and potyviruses; (v) proteolytic treatment of the genomic RNA leads to loss of infectivity; and (vi) mutagenesis of Tyr-693 included in the putative VPg protein is lethal for HAstV replication, which strongly supports its functional role in the covalent link with the viral RNA.     

Expression of the potato leafroll luteovirus coat protein gene in transgenic potato plants inhibits viral infection

Transgenic potato plants, cultivar Désirée, were produced that contained the coat protein gene of potato leafroll luteovirus (PLRV). The transformed potato plants expressed the PLRV coat protein (CP) RNA sequences but accumulation of coat protein in transgenic tissues could not be detected. Upon inoculation with PLRV, the PLRV CP RNA expressing potato plants showed a reduced rate of virus multiplication.     

Molecular diagnostics of potato infections with PVY and PLRV by immunochromatography

An immunochromatography test system has been developed for molecular diagnostics of the potato virus Y and PLRV infection. To increase a low yield of PLRV and raise antibodies against the PLRV antigen, chimerical virus was constructed comprising the PLRV coat protein and recombinant RNA of a tobamovirus, in which capsid protein gene was replaced by the PLRV coat protein gene. Binary vector containing the DNA copy of the recombinant RNA was infectious, and yield of the chimerical virus increased up to 800 times in comparison with the wild type PLRV. On the basis of experience in the development of the diagnostics of viral and viroid infections, rational tactics are proposed for the mass laboratory and field diagnosis of viral infections on the molecular level.     

Cytochrome P450 Cyp4x1 is a major P450 protein in mouse brain

A novel cytochrome P450, CYP4x1, was identified in EST databases on the basis of similarity to a conserved region in the C-helix of the CYP4A family. The human and mouse CYP4x1 cDNAs were cloned and found to encode putative cytochrome P450 proteins. Molecular modelling of CYP4x1 predicted an unusual substrate binding channel for the CYP4 family. Expression of human CYP4x1 was detected in brain by EST analysis, and in aorta by northern blotting. The mouse cDNA was used to demonstrate that the Cyp4x RNA was expressed principally in brain, and at much lower levels in liver; hepatic levels of the Cyp4x1 RNA were not affected by treatment with the inducing agents phenobarbital, dioxin, dexamethasone or ciprofibrate, nor were the levels affected in PPARalpha-/- mice. A specific antibody for Cyp4x1 was developed, and shown to detect Cyp4x1 in brain; quantitation of the Cyp4x1 protein in brain demonstrated approximately 10 ng of Cyp4x1 protein.mg(-1) microsomal protein, showing that Cyp4x1 is a major brain P450. Immunohistochemical localization of the Cyp4x1 protein in brain showed specific staining of neurons, choroids epithelial cells and vascular endothelial cells. These data suggest an important role for Cyp4x1 in the brain.     

Tyrosine 3 of poliovirus terminal peptide VPg(3B) has an essential function in RNA replication in the context of its precursor protein, 3AB

Poliovirus (PV) VPg is a genome-linked protein that is essential for the initiation of viral RNA replication. It has been well established that RNA replication is initiated when a molecule of UMP is covalently linked to the hydroxyl group of a tyrosine (Y3) in VPg by the viral RNA polymerase 3D(pol), but it is not yet known whether the substrate for uridylylation in vivo is the free peptide itself or one of its precursors. The aim of this study was to use complementation analyses to obtain information about the true in vivo substrate for uridylylation by 3D(pol). Previously, it was shown that a VPg mutant, in which tyrosine 3 and threonine 4 were replaced by phenylalanine and alanine (3F4A), respectively, was nonviable. We have now tested whether wild-type forms of proteins 3B, 3BC, 3BCD, 3AB, 3ABC, and P3 provided either in trans or in cis could rescue the replication defect of the VPg(3F4A) mutations in the PV polyprotein. Our results showed that proteins 3B, 3BC, 3BCD, and P3 were unable to complement the RNA replication defect in dicistronic PV or dicistronic luciferase replicons in vivo. However, cotranslation of the P3 precursor protein allowed rescue of RNA replication of the VPg(3F4A) mutant in an in vitro cell-free translation-RNA replication system, but only poor complementation was observed when 3BC, 3AB, 3BCD, or 3ABC proteins were cotranslated in the same assay. Interestingly, only protein 3AB but not 3B and 3BC, when provided in cis by insertion of a wild-type 3AB coding sequence between the P2 and P3 domains of the polyprotein, supported the replication of the mutated genome in vivo. Elimination of cleavage between 3A and 3B in the complementing 3AB protein, however, led to a complete lack of RNA replication. Our results suggest that (i) VPg has to be delivered to the replication complex in the form of a large protein precursor (P3) to be fully functional in replication; (ii) the replication complex formed during PV replication in vivo is essentially inaccessible to proteins provided in trans, even if the complementing protein is translated from a different cistron of the same RNA genome; (iii) 3AB is the most likely precursor of VPg; and (iv) Y3 of VPg has an essential function in RNA replication in the context of both VPg and 3AB.     

Volatiles from potato plants infected with potato leafroll virus attract and arrest the virus vector, Myzus persicae (Homoptera: Aphididae)

The influence of viral disease symptoms on the behaviour of virus vectors has implications for disease epidemiology. Here we show that previously reported preferential colonization of potatoes infected by potato leafroll virus (genus Polerovirus) (luteovirus) (PLRV) by alatae of Myzus persicae, the principal aphid vector of PLRV, is influenced by volatile emissions from PLRV-infected plants. First, in our bioassays both differential immigration and emigration were involved in preferential colonization by aphids of PLRV-infected plants. Second, M. persicae apterae aggregated preferentially, on screening above leaflets of PLRV-infected potatoes as compared with leaflets from uninfected plants, or from plants infected with potato virus X (PVX) or potato virus Y (PVY). Third, the aphids aggregated preferentially on screening over leaflet models treated with volatiles collected from PLRV-infected plants as compared with those collected from uninfected plants. The specific cues eliciting the aphid responses were not determined, but differences between headspace volatiles of infected and uninfected plants suggest possible ones.     

A membrane-associated precursor to poliovirus VPg identified by immunoprecipitation with antibodies directed against a synthetic heptapeptide

A synthetic heptapeptide corresponding to the C-terminal sequence of the poliovirus genome protein (VPg) has been linked to bovine serum albumin and used to raise antibodies in rabbits. These antibodies precipitate not only VPg but also at least two more virus-specific polypeptides. The smaller polypeptide, denoted P3-9 (12,000 daltons), has been mapped by Edman degradation and by fragmentation with cyanogen bromide and determined to be the N-terminal cleavage product of polypeptide P3-1b, a precursor to the RNa polymerase. P3-9 contains the sequence of the basic protein VPg (22 amino acids) at its C terminus. As predicted by the known RNA sequence of poliovirus, P3-9 also contains a hydrophobic region of 22 amino acids preceding VPg, an observation suggesting that P3-9 may be membrane-associated. This was confirmed by fractionation of infected cells in the presence or absence of detergent. We speculate that P3-9 may be the donor of VPg to RNA chains in the membrane-bound RNa replication complex.     

Detection of Potato Leaf Roll Virus in Intact Sprout Disks by Enzyme-linked Immunosorbent Assay

Potato leaf roll virus (PLRV) was detected by enzyme-linked immunosorbent assay (ELISA) when intact sprout, stem or leaf tissue disks were substituted for leaf or tuber extracts as test samples. Absorbance (A₄₀₅) values increased with increasing number of disks per plate well. Readings with sprout disks were significantly higher than those with disks cut from other plant tissues or with tuber sap. A₄₀₅ values obtained by using 7 or 5 sprout disks per well were near the maximum oneobtained with leaf sap. PLRV was slightly more efficiently detected by ELISA in light sprout disks than in etiolated sprout ones. When ten out of 34 healthy tubers were replaced by PLRV-infected ones in the tuber indexing test, the diseased samples werereliably detected with 5 etiolated sprout disks per well. The sprout disk sampling technique should be useful for qualitative evaluation of PLRV infection in sprouted potato tubers without necessity to wound them and using sprouts not long enough for maceration.     

Mutagenesis of tyrosine 24 in the VPg protein is lethal for feline calicivirus

The genome of feline calicivirus (FCV) is an approximately 7.7-kb single-stranded positive-sense RNA molecule that is polyadenylated at its 3' end and covalently linked to a VPg protein (calculated mass, 12.6 kDa) at its 5' end. We performed a mutational analysis of the VPg protein in order to identify amino acids potentially involved in linkage to the genome and replication. The tyrosine residues at positions 12, 24, 76, and 104 were changed to alanines by mutagenesis of an infectious FCV cDNA clone. Viruses were recovered when Tyr-12, Tyr-76, or Tyr-104 of the VPg protein was changed to alanine, but virus was not recovered when Tyr-24 was changed to alanine. Growth properties of the recovered viruses were similar to those of the parental virus. We examined whether the amino acids serine, threonine, and phenylalanine could substitute for the tyrosine at position 24, but these mutations were lethal as well. A tyrosine at this relative position is conserved among all calicivirus VPg proteins examined thus far, suggesting that the VPg protein of caliciviruses, like those of picornaviruses and potyviruses, utilizes tyrosine in the formation of a covalent bond with RNA.     

The P2 of Wheat yellow mosaic virus rearranges the endoplasmic reticulum and recruits other viral proteins into replication‐associated inclusion bodies

Viruses commonly modify host endomembranes to facilitate biological processes in the viral life cycle. Infection by viruses belonging to the genus Bymovirus (family Potyviridae) has long been known to induce the formation of large membranous inclusion bodies in host cells, but their assembly and biological roles are still unclear. Immunoelectron microscopy of cells infected with the bymovirus Wheat yellow mosaic virus (WYMV) showed that P1, P2 and P3 are the major viral protein constituents of the membranous inclusions, whereas NIa‐Pro (nuclear inclusion‐a protease) and VPg (viral protein genome‐linked) are probable minor components. P1, P2 and P3 associated with the endoplasmic reticulum (ER), but only P2 was able to rearrange ER and form large aggregate structures. Bioinformatic analyses and chemical experiments showed that P2 is an integral membrane protein and depends on the active secretory pathway to form aggregates of ER membranes. In planta and in vitro assays demonstrated that P2 interacts with P1, P3, NIa‐Pro or VPg and recruits these proteins into the aggregates. In vivo RNA labelling using WYMV‐infected wheat protoplasts showed that the synthesis of viral RNAs occurs in the P2‐associated inclusions. Our results suggest that P2 plays a major role in the formation of membranous compartments that house the genomic replication of WYMV.     

A Conserved Interaction between a C-Terminal Motif in Norovirus VPg and the HEAT-1 Domain of eIF4G Is Essential for Translation Initiation

Translation initiation is a critical early step in the replication cycle of the positive-sense, single-stranded RNA genome of noroviruses, a major cause of gastroenteritis in humans. Norovirus RNA, which has neither a 5´ m⁷G cap nor an internal ribosome entry site (IRES), adopts an unusual mechanism to initiate protein synthesis that relies on interactions between the VPg protein covalently attached to the 5´-end of the viral RNA and eukaryotic initiation factors (eIFs) in the host cell. For murine norovirus (MNV) we previously showed that VPg binds to the middle fragment of eIF4G (4GM; residues 652–1132). Here we have used pull-down assays, fluorescence anisotropy, and isothermal titration calorimetry (ITC) to demonstrate that a stretch of ~20 amino acids at the C terminus of MNV VPg mediates direct and specific binding to the HEAT-1 domain within the 4GM fragment of eIF4G. Our analysis further reveals that the MNV C terminus binds to eIF4G HEAT-1 via a motif that is conserved in all known noroviruses. Fine mutagenic mapping suggests that the MNV VPg C terminus may interact with eIF4G in a helical conformation. NMR spectroscopy was used to define the VPg binding site on eIF4G HEAT-1, which was confirmed by mutagenesis and binding assays. We have found that this site is non-overlapping with the binding site for eIF4A on eIF4G HEAT-1 by demonstrating that norovirus VPg can form ternary VPg-eIF4G-eIF4A complexes. The functional significance of the VPg-eIF4G interaction was shown by the ability of fusion proteins containing the C-terminal peptide of MNV VPg to inhibit in vitro translation of norovirus RNA but not cap- or IRES-dependent translation. These observations define important structural details of a functional interaction between norovirus VPg and eIF4G and reveal a binding interface that might be exploited as a target for antiviral therapy.     

Characterization of protein-protein interactions critical for poliovirus replication: analysis of 3AB and VPg binding to the RNA-dependent RNA polymerase

Two critical interactions within the poliovirus RNA replication complex are those of the RNA-dependent RNA polymerase 3D with the viral proteins 3AB and VPg. 3AB is a membrane-binding protein responsible for the localization of the polymerase to the membranous vesicles at which replication occurs. VPg (a peptide comprising the 3B region of 3AB) is the 22-residue soluble product of 3AB cleavage and serves as the protein primer for RNA replication. The detailed interactions of these proteins with the RNA-dependent RNA polymerase 3D were analyzed to elucidate the precise roles of 3AB and VPg in the viral RNA replication complex. Using a membrane-based pull-down assay, we have identified a binding "hot-spot" spanning residues 100 to 104 in the 3B (VPg) region of 3AB which plays a critical role in mediating the interaction of 3AB with the polymerase. Isothermal titration calorimetry shows that the interaction of VPg with 3D is enthalpically driven, with a dissociation constant of 11 microM. Mutational analyses of VPg indicate that a subset of the residues important for 3AB-3D binding are also important for VPg-3D binding. Two residues in particular, P14 and R17, were shown to be absolutely critical for the binding interaction. This work provides the direct characterization of two binding interactions critical for the replication of this important class of viruses and identifies a conserved polymerase binding sequence responsible for targeting the polymerase.     

Regulation and intracellular localization of Saccharomyces cerevisiae strand exchange protein 1 (Sep1/Xrn1/Kem1), a multifunctional exonuclease.

The Saccharomyces cerevisiae strand exchange protein 1 (Sep1; also referred to as Xrn1, Kem1, Rar5, or Stp beta) catalyzes the formation of hybrid DNA from model substrates in vitro. The protein is also a 5'-to-3' exonuclease active on DNA and RNA. Multiple roles for the in vivo function of Sep1, ranging from DNA recombination and cytoskeleton to RNA turnover, have been proposed. We show that Sep1 is an abundant protein in vegetative S. cerevisiae cells, present at about 80,000 molecules per diploid cell. Protein levels were not changed during the cell cycle or in response to DNA-damaging agents but increased twofold during meiosis. Cell fractionation and indirect immunofluorescence studies indicated that > 90% of Sep1 was cytoplasmic in vegetative cells, and indirect immunofluorescence indicated a cytoplasmic localization in meiotic cells as well. The localization supports the proposal that Sep1 has a role in cytoplasmic RNA metabolism. Anti-Sep1 monoclonal antibodies detected cross-reacting antigens in the fission yeast Schizosccharomyces pombe, in Drosophila melanogaster embryos, in Xenopus laevis, and in a mouse pre-B-cell line.     

Protein is linked to the 5' end of poliovirus RNA by a phosphodiester linkage to tyrosine.

Purification and partial characterization of the poliovirus RNA-linked protein (VPg) are described. VPg has been freed from the RNA by ribonuclease digestion and phenol extraction. Gel filtration chromatography of VPg-pUp (labeled with 32P) in 0.5% sodium dodecyl sulfate or 6 M guanidine HCl indicates that it has a molecular weight of about 12,000. VPg is bound to the 5' end of poliovirion RNA by a phosphodiester bond between a tyrosine residue in the VPg molecule and the 5'-terminal uridine. After acid hydrolysis of [3H]tyrosine-labeled VPg-pU, free tyrosine can be released by venom phosphodiesterase. Acid hydrolysis of VPg-p labeled with either 32P or [3H] tyrosine yields tyrosine-phosphate. There appears to be only 1 tyrosine residue per VPg molecule.     

Identification of specific fragments containing the 5'' end of poliovirus RNA after ribonuclease III digestion.

The small protein (VPg) covalently linked to the 5' end of poliovirus Type 1 (PV-1) RNA has been labeled in vitro with 125I using the Bolton and Hunter reagent. The RNA is not degraded under the conditions used and nearly all the label enters VPg and not the poly-nucleotide chain. When this 125I-labeled RNA is cleaved with RNase III at low monovalent salt concentrations, one major 125I-labeled fragment, approximately 100 nucleotides long, is produced. The corresponding fragment from similar digests of 32P-labeled RNA has also been identified. The 32P-labeled fragment changes electrophoretic mobility after protease treatment indicating that it contains VPg. Furthermore, the RNase T1 oligonucleotide known to be at the 5' terminus of poliovirus RNA is found in T1 digests of the purified fragment. These results confirm that the fragment is derived from the 5' end of the RNA. This fragment will be useful in studies concerning the initiation of protein synthesis during poliovirus infection.