Expression of the Bottom-Component RNA of Cowpea Mosaic Virus: Evidence that the 60-Kilodalton VPg Precursor Is Cleaved into Single VPg and a 58-Kilodalton Polypeptide

Inhibition of cleavage of a plant viral polyprotein by an inhibitor activity present in wheat germ and cowpea embryos

In rabbit reticulocyte lysate, the bottom component RNA of cowpea mosaic virus directs the synthesis of a 200,000-molecular-weight precursor protein (200K protein) that is cleaved during synthesis by a reticulocyte enzyme to form a 32K protein and a 170K protein. Cleavage of the 200K protein was found to be effectively inhibited by inhibitor activity in wheat germ and cowpea embryo extracts. The inhibitor was nondialyzable, precipitatable by ammonium sulfate, and partially stable at high temperatures. The activity appeared to be specific in that it caused no inhibition of the secondary cleavage reactions (cleavage of the 170K protein) at concentrations that were sufficient to cause complete inhibition of the primary cleavage reaction (cleavage of the 200K protein).

Evidence That the 32,000-Dalton Protein Encoded by Bottom-Component RNA of Cowpea Mosaic Virus is a Proteolytic Processing Enzyme

Translation of middle-component RNA of cowpea mosaic virus in vitro produced two polypeptides of 95 and 105 kilodaltons (95K and 105K, respectively) with overlapping amino acid sequences, which were specifically cleaved by a protease encoded by the bottom-component RNA. The proteolytic cleavage was studied by the addition of antibodies raised against various bottom-component RNA-encoded proteins to extracts prepared from bottom-component RNA-inoculated cowpea protoplasts. Since antiserum to the 32K polypeptide efficiently inhibited the proteolytic activity of such extracts, although antiserum to VPg or to the 170K polypeptide did not, evidence was obtained which indicates that the 32K polypeptide represents the protease involved. Fractionation of proteolytically active extract by glycerol gradient centrifugation demonstrated that 32K polypeptides do not exist as free proteins but are aggregated to the bottom-component RNA-encoded 170K, 84K, 60K, or 58K polypeptides. Maximal proteolytic activity was observed for 32K polypeptides associated with 170K polypeptides, suggesting that the activity was unstable and confined to newly synthesized molecules.

Identification of potyviral amorphous inclusion protein as a nonstructural, virus-specific protein related to helper component

Antisera to amorphous inclusion (AI) proteins associated with infections by pepper mottle virus (PeMV) and the watermelon mosaic virus-1 strain of papaya ringspot virus (PRSV-W) were used to probe in vitro translation products of the viral RNAs. The major translation product of PeMV RNA in the rabbit reticulocyte lysate (RRL) system was a previously reported polypeptide of apparent molecular weight 78,000 (Mr 78K). It reacted with anti-AI serum, whereas the major translation product in the wheat germ (WG) system was a 30K polypeptide that did not react with the antiserum. These results, the Mr values, and analyses of peptides generated by partial digestion with proteinase indicate that the amino acid sequences of the 30K polypeptide and the (Mr) 51K AI protein are distinct subsets of the 78K polypeptide amino acid sequence. Similar results were obtained with PRSV-W except that the Mr values of the corresponding translation products are 110K (RRL) and 60K (WG). Thus the 5'-most region of the PeMV and PRSV-W RNAs (corresponding to 78K and 110K, respectively) appears to encode two proteins rather than one as previously supposed on the basis of RRL translation products. Reciprocal serological tests revealed that the tobacco vein mottling virus aphid transmission helper component protein was related to AI protein. There is direct evidence that the AI represent another potyviral-coded nonstructural protein and the first evidence that a biologically functional protein is related to a component of a potyviral inclusion.

Mutational analysis of the genome-linked protein of cowpea mosaic virus

In this study we have performed a mutational analysis of the cowpea mosaic comovirus (CPMV) genome-linked protein VPg to discern the structural requirements necessary for proper functioning of VPg. Either changing the serine residue linking VPg to RNA at a tyrosine or a threonine or changing the position of the serine from the N-terminal end to position 2 or 3 abolished virus infectivity. Some of the mutations affected the cleavage between the VPg and the 58K ATP-binding protein in vitro, which might have contributed to the lethal phenotype. RNA replication of some of the mutants designed to replace VPg with the related cowpea severe mosaic comovirus was completely abolished, whereas replication of others was not affected or only mildly affected, showing that amino acids that are not conserved between the comoviruses can be critical for the function of VPg. The replicative proteins of one of the mutants failed to accumulate in typical cytopathic structures and this might reflect the involvement of VPg in protein-protein interactions with the other replicative proteins.

Cloning and sequencing of peach rosette mosaic virus RNA1

The complete nucleotide sequence of peach rosette mosaic nepovirus (PRMV) RNA1 has been determined. A grapevine isolate of PRMV from Michigan was propagated and purified and cDNA clones representing 99. 5% of the RNA1 were constructed. The cDNA and direct RNA sequence analysis revealed a RNA species of 8004 nucleotides, excluding a 3' polyadenylated tail. The 5'- and 3'-untranslated regions were 52 and 1474 nucleotides, respectively. Computer analysis of the PRMV RNA1 nucleotide sequence unveiled a single long open reading frame of 6477 nucleotides, which is capable of encoding a 240 kDa polyprotein. Analysis of the predicted amino acid sequence of RNA1 revealed amino acid motifs characteristic of a replicase, proteinase, NTP-binding protein and a proteinase cofactor. The order and identity of these putative proteins are consistent with other nepoviruses. Analysis of PRMV RNA1 further distinguishes the taxonomic subdivisions within the nepovirus group, confirms the subgroup three status of PRMV and lays the groundwork for a replicase-mediated resistance strategy.

Immunodetection of the 33 K/92 K polymerase proteins in cymbidium ringspot virus-infected and in transgenic plant tissue extracts

An antiserum was raised against the 33 K protein encoded by the 5' proximal gene of cymbidium ringspot tombusvirus RNA. This antiserum reacts specifically with the 33 K and 92 K proteins, which constitute the viral replicase, in CyRSV-infected Nicotiana benthamiana plants and in transgenic plants transformed with the full-length replicase gene. In inoculated leaves of infected plants, synthesis of the 33 K/92 K proteins stops ten days after inoculation, whereas in newly produced systemically infected leaves there was continuous production of these proteins. In transgenic plants, both proteins were detected showing that readthrough of the termination codon of the 33 K protein does not depend on the presence of the replicating virus. The subcellular localization of the 33 K/92 K proteins is similar in infected and transgenic plants. No correlation was found between the level of expression of integrated virus gene and level of resistance to the challenging virus.

Processing of VPg-containing polyproteins encoded by the B-RNA from cowpea mosaic virus

To study the processing of putative VPg precursors the expression of specific mutant transcripts derived from a full-length cDNA clone of cowpea mosaic virus (CPMV) B-RNA was examined in a rabbit reticulocyte lysate system. This study revealed that the 170K protein produced by a B-RNA mutant that lacks the 32K coding region was efficiently processed by mainly intramolecular cleavages at three different sites into three sets of proteins of 60K + 110K, 84K + 87K, and 58K + 112K. Further cleavage of the 60K protein into 58K and VPg has not been observed in this in vitro system. The 84K protein can be further processed by an intramolecular cleavage reaction via two alternative pathways, either into 26K (VPg + 24K) and 58K proteins or into 24K and 60K proteins. VPg can be released from the 112K (VPg + 110K) precursor either directly or via the 26K intermediate. Immunoblot analysis showed that the 112K protein is present in CPMV-infected plant cells indicating that the in vitro observations may hold true in vivo.

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.

Nucleotide sequence of Hungarian grapevine chrome mosaic nepovirus RNA1

The nucleotide sequence of the RNA1 of hungarian grapevine chrome mosaic virus, a nepovirus very closely related to tomato black ring virus, has been determined from cDNA clones. It is 7212 nucleotides in length excluding the 3' terminal poly(A) tail and contains a large open reading frame extending from nucleotides 216 to 6971. The presumably encoded polyprotein is 2252 amino acids in length with a molecular weight of 250 kDa. The primary structure of the polyprotein was compared with that of other viral polyproteins, revealing the same general genetic organization as that of other picorna-like viruses (comoviruses, potyviruses and picornaviruses), except that an additional protein is suspected to occupy the N-terminus of the polyprotein.

Proteolytic activity of the cowpea mosaic virus encoded 24K protein synthesized in Escherichia coli

The function of the 24-kilodalton (24K) protein encoded by cowpea mosaic virus (CPMV) has been studied by constructing a bacterial expression plasmid that contained a cloned chimeric segment consisting of partial DNA copies of CPMV M-RNA (including sequences coding for both capsid proteins) and B-RNA (including sequences coding for the 24K protein). Viral sequences were transcribed from the phage T7 promoter phi 10 of plasmid pT7-6 using T7-RNA polymerase expressed from plasmid pGP1-2 present in the same cells. Upon inducing the synthesis of T7-RNA polymerase several new polypeptides that contained CPMV-specific sequences were expressed, as demonstrated by immunoprecipitation and immunoblotting. Furthermore a proteolytic activity was detected in induced cells which cleaved the viral protein sequences specifically at two glutamine-glycine sites. One of the cleavage products represented capsid protein VP23. The proteolytic activity was absent when an 87-bp deletion was introduced in the coding region for the 24K protein, indicating that this protein represented the protease involved in the proteolytic processing at those specific sites.

Detection of a Novel Protein Encoded by the Bottom-Component RNA of Cowpea Mosaic Virus, Using Antibodies Raised against a Synthetic Peptide

A peptide was synthesized that corresponded to a sequence in the cowpea mosaic virus bottom-component RNA-encoded 200-kilodalton polyprotein showing homology to the picornaviral 3C proteases. By injecting a rabbit with this peptide, antibodies were obtained that allowed the detection of a novel viral protein derived from the 200-kilodalton polyprotein. This protein, which had a size of 24 kilodaltons was found in both infected cowpea leaves and cowpea protoplasts.

Determination of the Proteolytic Processing Sites in the Polyprotein Encoded by the Bottom-Component RNA of Cowpea Mosaic Virus

The bottom-component RNA (B-RNA) of cowpea mosaic virus is expressed by the production of a ∼200,000-dalton polyprotein (200K polyprotein), from which the functional proteins are formed by specific proteolytic cleavages. Partial amino-terminal sequences of the various B-RNA-encoded proteins have now been determined. Comparison of the information obtained with the B-RNA sequence allowed the localization of the coding regions for these proteins on B-RNA, the calculation of their precise molecular weights, and the determination of the cleavage sites at which they are released from the polyprotein precursor. Sequence analysis of the 32K protein, which is derived from the amino-terminal end of the 200K polyprotein, indicated that the AUG codon at nucleotide position 207 of the RNA sequence is the translation initiation codon. Sequence analysis of the 170K, 110K, 87K, 84K, 60K, and 58K proteins revealed the existence of three types of cleavage site in the 200K polyprotein: glutamine-serine (two sites), glutamine-methionine (one site), and glutamine-glycine (one site) amino acid pairs. The nature of these cleavage sites suggested that two different viral proteases are involved in the processing of the B-RNA-encoded polyprotein.

Cleavage of a viral polyprotein by a cellular proteolytic activity

The 200,000-dalton polyprotein encoded by the bottom component RNA of cowpea mosaic virus was synthesized in rabbit reticulocyte lysates, and this in vitro-synthesized protein was isolated from the lysate reaction mixture by sucrose density gradient centrifugation. Incubation of the isolated polyprotein with buffer caused no change in the protein, but incubation with reticulocyte lysates or with fractionated lysate proteins resulted in cleavage of the protein into the expected cleavage products (32,000- and 170,000-dalton proteins). This finding indicated that reticulocytes contain a proteolytic activity that is needed for the primary cleavage reaction. A cleavage assay in which we used partially purified preparations showed that cleavage was an ATP-dependent reaction.

RNA and capsid accumulation in cowpea protoplasts that are resistant to cowpea mosaic virus strain SB

Leaf protoplasts from the Arlington line of cowpea (Vigna unguiculata) support only a limited increase of cowpea mosaic virus strain SB (CPMV-SB), whereas cowpea severe mosaic virus, another member of the comovirus group, replicates efficiently in Arlington cowpea protoplasts. CPMV-SB replicates efficiently in protoplasts of cowpea line Blackeye 5. Some characteristics of the virus-specific resistance of Arlington protoplasts to CPMV-SB are reported. Differences between progeny CPMV-SB from Arlington and Blackeye 5 protoplasts were not detected. Inoculation with CPMV-SB RNA, rather than virions, did not make Arlington protoplasts fully susceptible. These results favor, for likely involvement in the CPMV-SB restriction phenomenon, events in the virus life cycle that occur after exposure of virion RNA to the cytoplasm and before assembly of particles is completed. The accumulation of CPMV-SB RNAs of both polarities was found to be depressed in inoculated Arlington protoplasts. However, (+)RNA (virion RNA polarity) accumulated to no lesser extent, per unit of (-)RNA, in Arlington protoplasts than in Blackeye 5 protoplasts. Capsid antigen accumulation, per unit of (+)RNA, was reduced in Arlington protoplasts as compared to Blackeye 5 protoplasts. A working hypothesis consistent with the above and other observations is that Arlington protoplasts have an inhibitory substance that interferes with the production or/and function of CPMV-SB specified proteins.

Homologous sequences in non-structural proteins from cowpea mosaic virus and picornaviruses

Computer analyses have revealed sequence homology between two non-structural proteins encoded by cowpea mosaic virus (CPMV), and corresponding proteins encoded by two picornaviruses, poliovirus and foot-and-mouth disease virus. A region of 535 amino acids in the 87-K polypeptide from CPMV was found to be homologous to the RNA-dependent RNA polymerases from both picornaviruses, the best matches being found where the picornaviral proteins most resemble each other. Additionally, the 58-K polypeptide from CPMV and polypeptide P2-X from poliovirus contain a conserved region of 143 amino acids. Based on the homology observed, a genetic map of the CPMV genome has been constructed in which the 87-K polypeptide represents the core polymerase domain of the CPMV replicase. These results have implications for the evolution of RNA viruses, and mechanisms are discussed which may explain the existence of homology between picornaviruses (animal viruses with single genomic RNAs) and comoviruses (plant viruses with two genomic RNAs).

Membrane fractions active in poliovirus RNA replication contain VPg precursor polypeptides

The poliovirus specific polypeptide P3-9 is of special interest for studies of viral RNA replication because it contains a hydrophobic region and, separated by only seven amino acids from that region, the amino acid sequence of the genome-linked protein VPg. Membraneous complexes of poliovirus-infected HeLa cells that contain poliovirus RNA replicating proteins have been analyzed for the presence of P3-9 by immunoprecipitation. Incubation of a membrane fraction rich in P3-9 with proteinase leaves the C-terminal 69 amino acids of P3-9 intact, an observation suggesting that this portion is protected by its association with the cellular membrane. These studies have also revealed two hitherto undescribed viral polypeptides consisting of amino acid sequences of the P2 and P3 regions of the polyprotein. Sequence analysis of stepwise Edman degradation show that these proteins are 3b/9 (Mr 77,000) and X/9 (Mr 50,000). 3b/9 and X/9 are membrane bound and are turned over rapidly and may be direct precursors to proteins P2-X and P3-9 of the RNA replication complex. P2-X, a polypeptide void of hydrophobic amino acid sequences but also found associated with membranes, is rapidly degraded when the membraneous complex is treated with trypsin. It is speculated that P2-X is associated with membranes by its affinity to the N-terminus of P3-9.

Orientation of the Cleavage Map of the 200-Kilodalton Polypeptide Encoded by the Bottom-Component RNA of Cowpea Mosaic Virus

The genomic organization of the bottom-component RNA of cowpea mosaic virus was studied. In vivo, this RNA encodes at least eight different polypeptides of 170, 110, 87, 84, 60, 58, 32, and 4 kilodaltons (K), the last polypeptide representing the genome-bound protein VPg. In rabbit reticulocyte lysates, bottom-component RNA is translated into a 200K polypeptide which is then processed to give the 32 and 170K polypeptides also found in vivo. By pulse-labeling the 200K primary translation product, we now show that the 32 and 170K polypeptides are derived from the NH 2 -terminal and COOH-terminal parts of this polypeptide, respectively. Comparison of the proteolytic peptide patterns of 170K polypeptides synthesized in vitro and pulse-labeled at either the NH 2 -terminal or the COOH-terminal end with the patterns of the 170 and 110K polypeptides found in vivo demonstrates that the order within the 200K primary translation product of cowpea mosaic virus bottom-component RNA is as follows: NH 2 -32K polypeptide-58K polypeptide-VPg-24K polypeptide-87K polypeptide-COOH.

Cowpea Mosaic Virus-Encoded Protease Does Not Recognize Primary Translation Products of M RNAs from Other Comoviruses

The protease encoded by the large (B) RNA segment of cowpea mosaic virus was tested for its ability to recognize the in vitro translation products of the small (M) RNA segment from the comoviruses squash mosaic virus, red clover mottle virus, and cowpea severe mosaic virus (CPsMV, strains Dg and Ark), and from the nepovirus tomato black ring virus. Like M RNA from cowpea mosaic virus, the M RNAs from squash mosaic virus, red clover mottle virus, CPsMV-Dg, and CPsMV-Ark were all translated into two large polypeptides with apparent molecular weights which were different for each virus and even for the two CPsMV strains. Neither the in vitro products from squash mosaic virus, red clover mottle virus, and CPsMV M RNAs nor the in vitro product from tomato black ring virus RNA-2 were processed by the cowpea mosaic virus-encoded protease, indicating that the activity of this enzyme is highly specific.