The VPg of tobacco etch virus RNA is the 49-kDa proteinase or the N-terminal 24-kDa part of the proteinase

A specific interaction between coat protein and helper component correlates with aphid transmission of a potyvirus

Specific binding between the coat protein (CP) and the helper component (HC) of the tobacco vein mottling potyvirus (TVMV) was characterized using a protein blotting-overlay protocol. In this in vitro assay, HC interacted with either virions or CP monomers originating from the aphid-transmissible TVMV-AT but not from the non-aphid-transmissible TVMV-NAT. There was a strong correlation between the aphid transmissibility of a series of TVMV variants having mutations in the DAG motif of the CP and their ability to bind HC. Expression of TVMV CP derivatives in bacteria allowed a precise determination of the minimum domain mediating HC binding. This domain is composed of seven amino acids, including the DAG motif (DTVDAGK), located in the N-terminus of the TVMV CP at amino acid positions 2 to 8.

Functions of the tobacco etch virus RNA polymerase (NIb): subcellular transport and protein-protein interaction with VPg/proteinase (NIa)

The NIb protein of tobacco etch potyvirus (TEV) possesses several functions, including RNA-dependent RNA polymerase and nuclear translocation activities. Using a reporter protein fusion strategy, NIb was shown to contain two independent nuclear localization signals (NLS I and NLS II). NLS I was mapped to a sequence within amino acid residues 1 to 17, and NLS II was identified between residues 292 and 316. Clustered point mutations resulting in substitutions of basic residues within the NLSs were shown previously to disrupt nuclear translocation activity. These mutations also abolished TEV RNA amplification when introduced into the viral genome. The amplification defects caused by each NLS mutation were complemented in trans within transgenic cells expressing functional NIb, although the level of complementation detected for each mutant differed significantly. Combined with previous results (X. H. Li and J. C. Carrington, Proc. Natl. Acad. Sci. USA 92:457-461, 1995), these data suggest that the NLSs overlap with essential regions necessary for NIb trans-active function(s). The fact that NIb functions in trans implies that it must interact with one or more other components of the genome replication apparatus. A yeast two-hybrid system was used to investigate physical interactions between NIb and several other TEV replication proteins, including the multifunctional VPg/proteinase NIa and the RNA helicase CI. A specific interaction was detected between NIa and NIb. Deletion of any of five regions spanning the NIb sequence resulted in NIb variants that were unable to interact with NIa. Clustered point mutations affecting the conserved GDD motif or NLS II within the central region of NIb, but not mutations affecting NLS I near the N terminus, reduced or eliminated the interaction. The C-terminal proteinase (Pro) domain of NIa, but not the N-terminal VPg domain, interacted with NIb. The effects of NIb mutations within NLS I, NLS II, and the GDD motif on the interaction between the Pro domain and NIb were identical to the effects of these mutations on the interaction between full-length NIa and NIb. These data are compatible with a model in which NIb is directed to replication complexes through an interaction with the Pro domain of NIa.

Three-dimensional model of the potyviral genome-linked protein

The full sequence of the genome-linked viral protein (VPg) cistron located in the central part of potato virus Y (common strain) genome has been identified. The VPg gene codes for a protein of 188 amino acids, with significant homology to other known potyviral VPg polypeptides. A three-dimensional model structure of VPg is proposed on the basis of similarity of hydrophobic-hydrophilic residue distribution to the sequence of malate dehydrogenase of known crystal structure. The 5' end of the viral RNA can be fitted to interact with the protein through the exposed hydroxyl group of Tyr-64, in agreement with experimental data. The complex favors stereochemically the formation of a phosphodiester bond [5'-(O4-tyrosylphospho)adenylate] typical for representatives of picornavirus-like viruses. The chemical mechanisms of viral RNA binding to VPg are discussed on the basis of the model structure of protein-RNA complex.

Analysis of the VPg-proteinase (NIa) encoded by tobacco etch potyvirus: effects of mutations on subcellular transport, proteolytic processing, and genome amplification

A mutational analysis was conducted to investigate the functions of the tobacco etch potyvirus VPg-proteinase (NIa) protein in vivo. The NIa N-terminal domain contains the VPg attachment site, whereas the C-terminal domain contains a picornavirus 3C-like proteinase. Cleavage at an internal site separating the two domains occurs in a subset of NIa molecules. The majority of NIa molecules in TEV-infected cells accumulate within the nucleus. By using a reporter fusion strategy, the NIa nuclear localization signal was mapped to a sequence within amino acid residues 40 to 49 in the VPg domain. Mutations resulting in debilitation of NIa nuclear translocation also debilitated genome amplification, suggesting that the NLS overlaps a region critical for RNA replication. The internal cleavage site was shown to be a poor substrate for NIa proteolysis because of a suboptimal sequence context around the scissile bond. Mutants that encoded NIa variants with accelerated internal proteolysis exhibited genome amplification defects, supporting the hypothesis that slow internal processing provides a regulatory function. Mutations affecting the VPg attachment site and proteinase active-site residues resulted in amplification-defective viruses. A transgenic complementation assay was used to test whether NIa supplied in trans could rescue amplification-defective viral genomes encoding altered NIa proteins. Neither cells expressing NIa alone nor cells expressing a series of NIa-containing polyproteins supported increased levels of amplification of the mutants. The lack of complementation of NIa-defective mutants is in contrast to previous results obtained with RNA polymerase (NIb)-defective mutants, which were relatively efficiently rescued in the transgenic complementation assay. It is suggested that, unlike NIb polymerase, NIa provides replicative functions that are cis preferential.

Construction and analysis of infectious transcripts from a resistance-breaking strain of tobacco vein mottling potyvirus

The Burley tobacco (Nicotiana tabacum) cultivar TN 86 is "resistant" to most strains of tobacco vein mottling potyvirus (TVMV), the virus being restricted to epidermal cells of inoculated leaves. One strain, designated TVMV-S, overcomes this resistance and infects cv TN 86 systemically. To begin our investigation of the molecular basis for the resistance-breaking phenomenon, we have completed the cloning and sequencing of the TVMV-S RNA genome. The complete cDNA clone, under the control of a T7 RNA polymerase promoter, was used to produce infectious transcripts which were tested for their ability to reproduce the characteristics of TVMV-S RNA on three types of tobacco (N. tabacum cv TN 86, N. tabacum cv KY 14, and N. benthamiana). Timing of symptom appearance, symptom type, and titer of virus were identical to those of plants inoculated with TVMV-S RNA. As a step toward mapping the responsible genetic region(s) that contribute(s) to resistance-breaking by TVMV-S, the nucleotide and deduced amino acid sequences were compared to those of wild-type TVMV, a strain that does not overcome cv TN 86 resistance. Variant TVMV-S transcripts containing changes within the VPg cistron exhibited an altered pattern of infectivity on cv TN 86.

Debilitation of plant potyvirus infectivity by P1 proteinase-inactivating mutations and restoration by second-site modifications

Tobacco etch virus (TEV) encodes three proteinases that catalyze processing of the genome-encoded polyprotein. The P1 proteinase originates from the N terminus of the polyprotein and catalyzes proteolysis between itself and the helper component proteinase (HC-Pro). Mutations resulting in substitution of a single amino acid, small insertions, or deletions were introduced into the P1 coding sequence of the TEV genome. Deletion of the N-terminal, nonproteolytic domain of P1 had only minor effects on virus infection in protoplasts and whole plants. Insertion mutations that did not impair proteolytic activity had no measurable effects regardless of whether the modification affected the N-terminal nonproteolytic or C-terminal proteolytic domain. In contrast, three mutations (termed S256A, F, and delta 304) that debilitated P1 proteolytic activity rendered the virus nonviable, whereas a fourth proteinase-debilitating mutation (termed C) resulted in a slow-infection phenotype. A strategy was devised to determine whether the defect in the P1 mutants was due to an inactive proteinase domain or due simply to a lack of proteolytic maturation between P1 and HC-Pro. Sequences coding for a surrogate cleavage site recognized by the TEV NIa proteinase were inserted into the genome of each processing-debilitated mutant at positions that resulted in NIa-mediated proteolysis between P1 and HC-Pro. The infectivity of each mutant was restored by these second-site modifications. These data indicate that P1 proteinase activity is not essential for viral infectivity but that separation of P1 and HC-Pro is required. The data also provide evidence that the proteinase domain is involved in additional, nonproteolytic functions.

The tobacco etch potyvirus 6-kilodalton protein is membrane associated and involved in viral replication

The tobacco etch potyvirus (TEV) genome encodes a polyprotein that is processed by three virus-encoded proteinases. Although replication of TEV likely occurs in the cytoplasm, two replication-associated proteins, VPg-proteinase (nuclear inclusion protein a) (NIa) and RNA-dependent RNA polymerase (nuclear inclusion protein b) (NIb), accumulate in the nucleus of infected cells. The 6-kDa protein is located adjacent to the N terminus of NIa in the TEV polyprotein, and, in the context of a 6-kDa protein/NIa (6/NIa) polyprotein, impedes nuclear translocation of NIa (M. A. Restrepo-Hartwig and J. C. Carrington, J. Virol. 66:5662-5666, 1992). The 6-kDa protein and three polyproteins containing the 6-kDa protein were identified by affinity chromatography of extracts from infected plants. Two of the polyproteins contained NIa or the N-terminal VPg domain of NIa linked to the 6-kDa protein. To investigate the role of the 6-kDa protein in vivo, insertion and substitution mutagenesis was targeted to sequences coding for the 6-kDa protein and its N- and C-terminal cleavage sites. These mutations were introduced into a TEV genome engineered to express the reporter protein beta-glucuronidase (GUS), allowing quantitation of virus amplification by a fluorometric assay. Three-amino-acid insertions at each of three positions in the 6-kDa protein resulted in viruses that were nonviable in tobacco protoplasts. Disruption of the N-terminal cleavage site resulted in a virus that was approximately 10% as active as the parent, while disruption of the C-terminal processing site eliminated virus viability. The subcellular localization properties of the 6-kDa protein were investigated by fractionation and immunolocalization of 6-kDa protein/GUS (6/GUS) fusion proteins in transgenic plants. Nonfused GUS was associated with the cytosolic fraction (30,000 x g centrifugation supernatant), while 6/GUS and GUS/6 fusion proteins sedimented with the crude membrane fraction (30,000 x g centrifugation pellet). The GUS/6 fusion protein was localized to apparent membranous proliferations associated with the periphery of the nucleus. These data suggest that the 6-kDa protein is membrane associated and is necessary for virus replication.

Families of cysteine peptidases

This chapter presents families of cysteine peptidases. The activity of all cysteine peptidases depends on a catalytic dyad of cysteine and histidine. The order of the cysteine and histidine residues (Cys/His or His/Cys) in the linear sequence differs between families and this is among the lines of evidence suggesting that cysteine peptidases have had many separate evolutionary origins. The families C1, C2, and C10 can be described as “papainlike,” and form clan CA. The papain family contains peptidases with a wide variety of activities, including endopeptidases with broad specificity, endopeptidases with narrow specificity, aminopeptidases, and peptidases with both endopeptidase and exopeptidase activities. Papain homologs are generally either lysosomal or secreted proteins. The calpain family includes the calcium-dependent cytosolic endopeptidase calpain, which is known from birds and mammals, and the product of the sol gene in Drosophila. Calpain is a complex of two peptide chains. Picornains are a family of polyprotein-processing endopeptidases from single-stranded RNA viruses. Each picornavirus has two picornains (2A and 3C).

Internal cleavage and trans-proteolytic activities of the VPg-proteinase (NIa) of tobacco etch potyvirus in vivo

The NIa protein of plant potyviruses is a bifunctional protein containing an N-terminal VPg domain and a C-terminal proteinase region. The majority of tobacco etch potyvirus (TEV) NIa molecules are localized to the nucleus of infected cells, although a proportion of NIa is attached covalently as VPg to viral RNA in the cytoplasm. A suboptimal cleavage site that is recognized by the NIa proteinase is located between the two domains. This site was found to be utilized in the VPg-associated, but not the nuclear, pool of NIa. A mutation converting Glu-189 to Leu at the P1 position of the processing site inhibited internal cleavage. Introduction of this mutation into TEV-GUS, an engineered variant of TEV that expresses a reporter protein (beta-glucuronidase [GUS]) fused to the N terminus of the helper component-proteinase (HC-Pro), rendered the virus replication defective in tobacco protoplasts. Site-specific reversion of the mutant internal processing site to the wild-type sequence restored virus viability. In addition, the trans-processing activity of NIa proteinase was tested in vivo after introduction of an artificial cleavage site between the GUS and HC-Pro sequences in the cytoplasmic GUS/HC-Pro polyprotein encoded by TEV-GUS. The novel site was recognized and processed in plants infected by the engineered virus, indicating the presence of excess NIa processing capacity in the cytoplasm. The potential roles of internal NIa processing in TEV-infected cells are discussed.

Plants that express a potyvirus proteinase gene are resistant to virus infection

Transgenic tobacco plants that express the genome-linked protein/proteinase-coding region of the potyvirus tobacco vein mottling virus (TVMV) were produced and tested for their reaction to inoculation with TVMV and two other potyviruses. These plants did not develop disease symptoms after being inoculated with large doses of TVMV but were as susceptible to infection by the other potyviruses as were control plants. Lines of tobacco that express the coat protein- or the nonstructural cylindrical inclusion protein-coding regions were also produced. The coat protein transgenic plants were protected against all three potyviruses, and the cylindrical inclusion transgenic plants were susceptible to all three potyviruses. These results indicate that some, but not all, TVMV genes can be used to confer protection against potyviruses in plants. The results also suggest that combinations of viral genes in transgenic plants might improve protection against potyviruses.

The complete nucleotide sequence of pepper mottle virus genomic RNA: comparison of the encoded polyprotein with those of other sequenced potyviruses

The complete nucleotide sequence of a pepper mottle virus isolate from California (PepMoV C) has been determined from cloned viral cDNAs. The PepMoV C genomic RNA is 9640 nucleotides excluding the poly(A) tail and contains a long open reading frame starting at nucleotide 168 and potentially encoding a polyprotein of 3068 amino acids. Comparison of the PepMoV C presumptive polyprotein with those of other sequenced members of the potyvirus group, including tobacco etch virus (TEV), tobacco vein mottling virus (TVMV), plum pox virus (PPV), and potato virus Y (PVY), allowed localization of putative protein cleavage sites. A similar analysis was used to determine the position of conserved viral protein-coding regions along the viral genomic RNA. These analyses confirm previous work indicating that genome organization is conserved among members of the genus Potyvirus. The localization of one PepMoV C gene product, the nuclear inclusion body protein a (NIa protein), was analyzed by expressing PepMoV cDNA deletion clones in bacteria and assaying for appearance of mature-sized coat protein, a cleavage product of the NIa protease. Comparative sequence analyses of the putative PepMoV polyprotein with those of TEV, TVMV, PPV, and PVY served to identify regions of the potyviral polyproteins which have diverged within the genus, as well as highly conserved protein features which may play an important functional role in the potyviral life cycle.

Mutational analysis of the tobacco etch potyviral 35-kDa proteinase: identification of essential residues and requirements for autoproteolysis

The tobacco etch potyvirus (TEV) polyprotein is processed by three virus-encoded proteinases, termed Nla, HC-Pro, and the 35-kDa proteinase. The 35-kDa proteinase is derived from the amino-terminal region of the polyprotein. Analysis of polyproteins containing beta-glucuronidase fused to the expected carboxy terminus of the 35-kDa proteinase confirmed the previously identified Tyr304-Ser305 dipeptide as the cleavage site between the 35-kDa proteinase and HC-Pro. The 35-kDa proteinase of TEV was unable to catalyze proteolysis when synthetic substrate polyproteins were supplied in a bimolecular or trans reaction, suggesting that processing occurs by an autolytic mechanism. The results of a mutational analysis within the 35-kDa proteolytic domain indicated that His214, Asp223, Ser256, and Asp288 were required for optimal autoproteolytic activity. Replacement of Ser256 with either Thr or Cys resulted in low but detectable proteinase activity, as did substitution of Asp223 and Asp288 with Glu. These results are consistent with the hypothesis that the 35-kDa proteinase resembles cellular serine-type proteinases, with Ser256 functioning as the nucleophilic residue within the active site. Cleavage mediated by the 35-kDa proteinase has been shown previously to occur after polyprotein synthesis in wheat germ extracts and transgenic plants, but not in rabbit reticulocyte lysate. We were able to demonstrate that processing in vitro may require a heat-labile factor present in wheat germ extracts.

Release of a 22-kDa protein derived from the amino-terminal domain of the 49-kDa NIa of turnip mosaic potyvirus in Escherichia coli

The coding region for the precursor 6K-small nuclear inclusion a (NIa) protein and for the NIa protein of turnip mosaic potyvirus (TuMV) were introduced into the plasmid pET-11d for high-level expression in Escherichia coli. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblot analyses of E. coli proteins showed that the NIa protein underwent endoproteolysis and released a 22-kDa polypeptide. NH2-terminal amino acid sequencing of the recombinant 22-kDa protein was performed and was identical to the predicted amino end of the NIa protein. Site-directed mutagenesis confirmed that the hydrolysis was associated with the NIa proteolytic activity and that the proteinase recognized a Glu residue within an amino acid sequence found in the NIa protein which fitted the TuMV consensus cleavage site sequence. Fusion of the 6K protein with the NIa protein partially inhibited the hydrolytic reaction. The recombinant 22-kDa protein is likely the VPg of TuMV.

Regulation of nuclear transport of a plant potyvirus protein by autoproteolysis

The NIa proteinase encoded by tobacco etch potyvirus catalyzes six processing events, three of which occur by an autoproteolytic mechanism. Autoproteolysis is necessary to cleave the boundaries of both NIa and the 6-kDa protein, which is located adjacent to the N terminus of NIa in the viral polyprotein. As a consequence, NIa may exist in a free form or in a transient polyprotein form containing the 6-kDa protein. While the majority of NIa molecules localize to the nuclei of infected cells, a fraction of the NIa pool is attached covalently to the 5' terminus of genomic RNA in the cytoplasm. To determine whether the presence of the 6-kDa protein affects the nuclear transport properties of NIa, we have generated transgenic plants that express genes encoding a reporter enzyme, beta-glucuronidase (GUS), fused to NIa or NIa-containing polyproteins. The NIa/GUS fusion protein was detected by histochemical analysis in the nucleus. Similarly, an NIa/GUS fusion protein that arose by autoproteolysis of a 6-kDa/NIa/GUS polyprotein was found in the nucleus. In contrast, fusion protein consisting of 6-kDa/NIa/GUS, which failed to undergo proteolysis because of the presence of a Cys-to-Ala substitution in the proteolytic domain of NIa, was detected in the cytoplasm. The inhibition of NIa-mediated nuclear transport was not due to the Cys-to-Ala substitution, since this alteration had no effect on translocation in the absence of the 6-kDa protein. These results indicate that the 6-kDa protein impedes nuclear localization of NIa and suggest that subcellular transport of NIa may be regulated by autoproteolysis.

Sequence upstream of the 24K protease enhances cleavage of the cowpea mosaic virus B RNA-encoded polyprotein at the junction between the 24K and 87K proteins

To investigate cleavage at the junction between the cowpea mosaic virus (CPMV) 24K and 87K proteins, plasmids were constructed containing the sequence of bottom-component (B) RNA encoding the 110K protein plus a variable length of upstream coding sequence. Transcripts derived from these clones were translated in rabbit reticulocyte lysate and the appearance of the 87K protein was used to assess the efficiency of cleavage at the 24K-87K junction. The results show that the 110K protein, containing the contiguous sequence of the 24K and 87K proteins, is stable and that efficient cleavage at 24K-87K junction requires the presence of amino acids upstream of the 24K protease. These observations show that the 170K protein rather than the 110K protein is the precursor of the 87K protein and suggest a mechanism whereby both the B RNA-encoded 110K and 87K proteins can accumulate during infection.

Serological relationships involving potyviral nonstructural proteins

This report represents a compilation of many of the publications on antigenic properties of potyviral-specified nonstructural proteins. Polyclonal antisera have been prepared for use in characterization of six nonstructural proteins. These include antisera to the cylindrical inclusion proteins of at least 28 potyviruses, to small nuclear inclusion protein (protease) of four potyviruses, to large nuclear inclusion protein (putative replicase) of three viruses, helper component-protease or amorphous inclusion protein of at least four viruses, to the P1 protein (located at the N-terminus of the polyprotein) of one virus, and to the P3 protein (located between helper component protease and cylindrical inclusion protein) of one virus. Monoclonal antibodies also have been prepared to several of these nonstructural proteins. The evidence thus far indicates that cylindrical inclusions of different potyviruses have both conserved and unique epitopes. Nuclear inclusion proteins and amorphous inclusion proteins also may have conserved and unique epitopes. Antigenic relationships of potyviral nonstructural proteins have potential for the identification and classification of potyviruses.

Two newly detected nonstructural viral proteins in potyvirus-infected cells

The existence of two viral RNA-encoded proteins in cells infected with tobacco vein mottling potyvirus (TVMV) has been demonstrated. One of the proteins (named 34K) maps at the N-terminus of the TVMV polyprotein and the other (42K) between the helper component and cylindrical inclusion proteins; both had previously been predicted in the consensus potyviral genetic map. The 34K and 42K coding regions of TVMV were cloned separately in a bacterial expression vector and the proteins were isolated from transformed Escherichia coli. These were used to raise polyclonal antibodies which reacted specifically with proteins of the expected size in immunoblots of extracts of TVMV-infected tobacco leaves and protoplasts. In addition to 42K, the anti-42K serum detected similar amounts of a second protein of apparent size 37 kDa that was absent in 42K-expressing bacteria. Both 34K and 42K were present predominantly in membrane-enriched fractions of extracts of TVMV-infected tobacco leaves. Computer analysis of the deduced amino acid sequence of 42K suggests that this viral protein may be an integral transmembrane protein.

The 35-kDa protein from the N-terminus of the potyviral polyprotein functions as a third virus-encoded proteinase

The polyprotein encoded by plant potyviruses is proteolytically processed to at least eight mature products by viral-encoded proteinases. While the proteinases that catalyze processing at most of the cleavage sites have been identified, the enzyme responsible for cleavage between the 35-kDa protein and helper component-proteinase (HC-Pro), near the N-terminus of the viral polyprotein, has not been mapped or characterized previously. Polyproteins containing the 35-kDa protein and HC-Pro were synthesized in the wheat germ system using defined RNA transcripts and were demonstrated to undergo proteolysis to generate products that resemble fully processed proteins. The C-terminal half of the 35-kDa protein was found to be required for proteolysis, whereas most of the HC-Pro sequence was dispensable. Amino acid substitutions affecting three positions, each of which are conserved in the 35-kDa protein encoded by five potyviruses, were shown to inhibit protein processing. These data suggest that the 35-kDa protein functions as a proteinase to cleave at its C-terminus. A model that accounts for all proteolytic processing events in the potyviral polyprotein is presented.

Identification of the initiation codon of plum pox potyvirus genomic RNA

The expression of plum pox potyvirus (PPV) genomic RNA takes place through translation of its unique long and functional open reading frame (ORF) into a large polyprotein that undergoes extensive proteolytic processing. In this paper we show that the AUG recognized as the initiation codon of the PPV ORF by in vitro translation systems is the one found at nucleotide position 147, in spite of the presence at position 36 of an in-phase AUG that marks the start of the ORF. Deletion of a substantial part of the PPV 5' nontranslated region (5'-NTR), from nucleotide 19 to 101, does not impair the in vitro translation of PPV synthetic transcripts. By introduction of mutations that disrupt either of these two AUGs into a full-length PPV cDNA clone, it is shown that, while alteration of the first AUG does not have any effect on virus viability, growth, or symptom induction, destruction of the second renders the viral RNA noninfectious. This result indicates that the AUG employed in vivo is also the second. The hypothesis that this AUG could be recognized through a ribosomal internal entry mechanism has been tested in vitro using various bicistronic transcripts in which the PPV 5'-NTR was internally placed. The second cistron of these bicistronic RNAs was translated, but only at low levels, indicating that the PPV 5'-NTR is not able to drive in vitro an efficient internal entry of the ribosomes and suggesting that PPV RNA translation might proceed through a conventional leaky scanning mechanism.

A determinant of disease symptom severity is located in the 3'-terminal noncoding region of the RNA of a plant virus

Inoculation of Nicotiana tabacum plants with RNA transcribed in vitro from a variant (pXBS8) of a cloned full-length DNA copy of tobacco vein mottling virus (TVMV) RNA resulted in attenuation of the vein mottling and blotching symptoms typically produced by transcripts of cloned wild-type cDNA (pXBS7). Similar amounts of virus were detected by ELISA (using anti-TVMV coat protein serum) in systemically infected leaves of plants inoculated with pXBS7 or pXBS8 transcripts. pXBS8 was shown to contain a 58-nucleotide segment in the sequence corresponding to the 3'-terminal untranslated region of TVMV RNA that was not present in pXBS7. This segment resulted in the appearance in pXBS8 transcripts of four adjacent direct repeats of a 14-nucleotide sequence, AUAAUUAUAUAUAU, that is present in the 3'-untranslated region of TVMV RNA, with two additional nucleotides (AU) between the first and second repeats. Insertion of restriction fragments containing the segment into pXBS7 and inoculation of plants with transcripts of the chimeric construct (pXBS78) resulted in the attenuated-symptom phenotype and was not accompanied by a reduced accumulation of virus in the plant as determined by ELISA and Northern blot analysis. When the extra nucleotides were removed from the variant clone, symptoms induced by transcripts of the cDNA (pXBS87) resembled those induced by wild-type transcripts. The results indicate that a noncoding region of the genome can have a direct effect on the induction of disease symptoms by an RNA virus.

Post-translational processing of the tobacco etch virus 49-kDa small nuclear inclusion polyprotein: identification of an internal cleavage site and delimitation of VPg and proteinase domains

The 49,000-dalton (49-kDa) small nuclear inclusion (NI) protein of tobacco etch virus (TEV) has two distinct functions associated with it. An N-terminal segment is covalently attached to the genomic length RNA and likely involved in RNA replication, while the C-terminal half is associated with a proteolytic activity critical for genome expression. The junction delineating these two proteins has not been identified. We have analyzed naturally occurring cleavage products of TEV NI proteins and have identified a possible internal cleavage site between Glu and Gly residues at TEV 49-kDa NI protein amino acids 189-190. Similar 49-kDa-derived products are formed in cell-free translation studies in minor amounts upon the addition of excess amounts of NI protein. Cleavage of the 49-kDa (430 amino acids) protein is predicted to result in the formation of two products, 21-kDa (189 amino acids) and 27 kDa (241 amino acids) in size. Complementary DNA encoding the 27-kDa C-terminal portion of the 49-kDa protein gene was cloned into various DNA sequences. This allowed us to express the 27-kDa protein alone or as part of higher molecular weight polyproteins containing flanking TEV or foreign protein sequences. This 27-kDa amino acid sequence had a proteolytic activity similar to the 49-kDa-associated activity.

Proteolytic activity of plum pox virus-tobacco etch virus chimeric NIa proteases

Plasmids encoding chimeric NIa-type proteases made of sequences from the potyviruses plum pox virus (PPV) and tobacco etch virus (TEV) have been constructed. Their proteolytic activity on the large nuclear inclusion protein (NIb)-capsid protein (CP) junction of each virus was assayed in Escherichia coli cells. The amino half of the protease seemed to be involved neither in the enzymatic catalysis nor in substrate recognition. In spite of the large homology among the PPV and TEV NIa-type proteases, the exchange of fragments from the carboxyl halves of the molecules usually caused a drastic decrease in the enzymatic activity. Inactive chimeric proteases did not interfere with cleavage by PPV wild type protease expressed from a second plasmid. The results suggest that the recognition and catalytic sites of the NIa proteases are closely interlinked and, although residues relevant for the correct interaction with the substrate could be present in other parts of the protein, a main determinant for substrate specificity should lie in a region situated, approximately, between positions 30 and 90 from the carboxyl end. This region includes the conserved His at position 360 of PPV or 355 of TEV, which has been postulated to interact with the Gln at position -1 of the cleavage sites.

A tyrosine residue in the small nuclear inclusion protein of tobacco vein mottling virus links the VPg to the viral RNA

The identity of the amino acid residue that links the VPg of the potyvirus tobacco vein mottling virus (TVMV) to the viral RNA was determined. 32P-labeled TVMV RNA was digested with RNase A and micrococcal nuclease. The resulting 32P-labeled VPg was isolated and partially hydrolyzed with 6 N HCl at 110 degrees C for 2 h. Analysis by thin-layer electrophoresis revealed the presence of [32P]phosphotyrosine but not [32P]phosphoserine or [32P]phosphothreonine. Another preparation of TVMV RNA was treated with endoproteinase Lys-C, and the resulting peptide-RNA was purified by sodium dodecyl sulfate-sucrose gradient centrifugation. The sequence of the N-terminal 15 amino acid residues of the peptide, when compared with the RNA-derived amino acid sequence of the TVMV polyprotein, demonstrated that the peptide occurs in the small nuclear inclusion protein. These data suggest that Tyr-1860 of the polyprotein is the amino acid residue that links the TVMV VPg to the viral RNA.

A point mutation in the coat protein abolishes aphid transmissibility of a potyvirus

A nonaphid transmissible (NAT) variant of tobacco vein mottling virus (TVMV) was used to test the hypothesis that the viral coat protein (CP) plays a role in determining aphid transmissibility. Comparison of the nucleotide sequences in the coat protein cistron of an aphid transmissible isolate (TVMV-AT) with that of TVMV-NAT revealed a single nucleotide difference (G----A) at position 8445; this alters a single amino acid residue (G----E) at position 2747. A cDNA fragment representing the CP region of TVMV-NAT was substituted into the CP region of a full-length cDNA clone of TVMV-AT, and transcribed RNA was inoculated to tobacco plants. Aphids were unable to transmit the resultant hybrid virus which had the TVMV-NAT coat protein, although the concentration and infectivity of the hybrid virus in the source plants were similar to those of TVMV-AT. This is the first direct demonstration that a CP mutation affects aphid transmissibility of a potyvirus.