Synthesis and proteolytic processing of cowpea mosaic virus proteins in reticulocyte lysates

Cowpea Mosaic Virus Outperforms Other Members of the Secoviridae as In Situ Vaccine for Cancer Immunotherapy

In situ vaccination for cancer immunotherapy uses intratumoral administration of small molecules, proteins, nanoparticles, or viruses that activate pathogen recognition receptors (PRRs) to reprogram the tumor microenvironment and prime systemic antitumor immunity. Cowpea mosaic virus (CPMV) is a plant virus that─while noninfectious toward mammals─activates mammalian PRRs. Application of CPMV as in situ vaccine (ISV) results in a potent and durable efficacy in tumor mouse models and canine patients; data indicate that CPMV outperforms small molecule PRR agonists and other nonrelated plant viruses and virus-like particles (VLPs). In this work, we set out to compare the potency of CPMV versus other plant viruses from the Secoviridae. We developed protocols to produce and isolate cowpea severe mosaic virus (CPSMV) and tobacco ring spot virus (TRSV) from plants. CPSMV, like CPMV, is a comovirus with genome and protein homology, while TRSV lacks homology and is from the genus nepovirus. When applied as ISV in a mouse model of dermal melanoma (using B16F10 cells and C57Bl6J mice), CPMV outperformed CPSMV and TRSV─again highlighting the unique potency of CPMV. Mechanistically, the increased potency is related to increased signaling through toll-like receptors (TLRs)─in particular, CPMV signals through TLR2, 4, and 7. Using knockout (KO) mouse models, we demonstrate here that all three plant viruses signal through the adaptor molecule MyD88─with CPSMV and TRSV predominantly activating TLR2 and 4. CPMV induced significantly more interferon β (IFNβ) compared to TRSV and CPSMV; therefore, IFNβ released upon signaling through TLR7 may be a differentiator for the observed potency of CPMV-ISV. Additionally, CPMV induced a different temporal pattern of intratumoral cytokine generation characterized by significantly increased inflammatory cytokines 4 days after the second of 2 weekly treatments, as if CPMV induced a "memory response". This higher, longer-lasting induction of cytokines may be another key differentiator that explains the unique potency of CPMV-ISV.

Infusion of imaging and therapeutic molecules into the plant virus-based carrier cowpea mosaic virus: cargo-loading and delivery

This work is focused on the development of a plant virus-based carrier system for cargo delivery, specifically 30nm-sized cowpea mosaic virus (CPMV). Whereas previous reports described the engineering of CPMV through genetic or chemical modification, we report a non-covalent infusion technique that facilitates efficient cargo loading. Infusion and retention of 130-155 fluorescent dye molecules per CPMV using DAPI (4',6-diamidino-2-phenylindole dihydrochloride), propidium iodide (3,8-diamino-5-[3-(diethylmethylammonio)propyl]-6-phenylphenanthridinium diiodide), and acridine orange (3,6-bis(dimethylamino)acridinium chloride), as well as 140 copies of therapeutic payload proflavine (PF, acridine-3,6-diamine hydrochloride), is reported. Loading is achieved through interaction of the cargo with the CPMV's encapsidated RNA molecules. The loading mechanism is specific; empty RNA-free eCPMV nanoparticles could not be loaded. Cargo-infused CPMV nanoparticles remain chemically active, and surface lysine residues were covalent modified with dyes leading to the development of dual-functional CPMV carrier systems. We demonstrate cargo-delivery to a panel of cancer cells (cervical, breast, and colon): CPMV nanoparticles enter cells via the surface marker vimentin, the nanoparticles target the endolysosome, where the carrier is degraded and the cargo is released allowing imaging and/or cell killing. In conclusion, we demonstrate cargo-infusion and delivery to cells; the methods discussed provide a useful means for functionalization of CPMV toward its application as drug and/or contrast agent delivery vehicle.

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).

Expression of Middle-Component RNA of Cowpea Mosaic Virus: In Vitro Generation of a Precursor to Both Capsid Proteins by a Bottom-Component RNA-Encoded Protease from Infected Cells

The expression of the middle-component (M) RNA of cowpea mosaic virus was studied by means of in vitro translation. In both the wheat germ extract and the rabbit reticulocyte lysate, M RNA was translated into two overlapping polypeptides of 95 and 105 kilodaltons. Incubation of these polypeptides with 30,000 x g supernatant fractions from cowpea mesophyll protoplasts inoculated with complete virus or with separate bottom (B) components alone resulted in extensive processing, yielding polypeptides of 60, 58, 48, and 47 kilodaltons. Similar proteolytic activity was found associated with the in vitro translation products from the bottom-component RNA, demonstrating that the protease present in infected cells is encoded by B RNA. Using antisera raised against the separate capsid proteins VP23 and VP37, it was shown that the 60-kilodalton cleavage product is the precursor to both capsid proteins. Cleavage of nascent 95- and 105- kilodalton polypeptides by the in vivo protease demonstrated that this capsid protein precursor is located C terminally within both polypeptides and that the synthesis of these two overlapping polypeptides is the result of two initiation sites on middle-component RNA. In addition, a second virus-induced proteolytic activity, capable of releasing VP23 from the 95- and 105-kilodalton polypeptides, was detected in leaves of infected plants, but not in infected mesophyll protoplasts. A model for the expression of the middle-component RNA is presented.

Synthesis of Black Beetle Virus Proteins in Cultured Drosophila Cells: Differential Expression of RNAs 1 and 2

Black beetle virus is an insect virus with a split genome consisting of two single-stranded, messenger-active RNA molecules with molecular weights of 1.0 x 10(6) (RNA 1) and 0.5 x 10(6) (RNA 2), respectively. Virions contained two proteins, beta with a molecular weight of 43,000 (43K) and gamma (5K), and traces of a third protein, alpha (47K). When translated in cell-free extracts of rabbit reticulocytes, RNA 1 directed the synthesis of protein A (104K), whereas RNA 2 synthesized protein alpha. The in vitro translation efficiency of the two RNAs was roughly equal. Infection of cultured Drosophila cells induced the synthesis of five new proteins: A, alpha, beta, gamma, and B (10K), detected by autoradiography of polyacrylamide gels after electrophoresis of extracts from [(35)S]methionine-labeled cultures. All but protein gamma could also be detected by staining with Coomassie brilliant blue, indicating vigorous synthesis of viral proteins. Pulse-chase experiments in infected cells revealed the disappearance of protein alpha and the coordinate appearance of proteins beta and gamma, supporting an earlier proposal that coat protein of mature virions is made by cleavage of precursor alpha. Proteins A and B were stable in such pulse-chase experiments. The three classes of virus-induced proteins, represented by A, B, and alpha, were synthesized in markedly different amounts and with different kinetics. Synthesis of proteins A and B peaked early in infection and then declined, whereas synthesis of coat protein precursor alpha peaked much later. These results suggest that RNA 1 controls early replication functions via protein A (and also possibly protein B), whereas RNA 2 controls synthesis of coat protein required later for virion assembly.

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.

Cowpea mosaic virus: the plant virus-based biotechnology workhorse

In the 50 years since it was first described, Cowpea mosaic virus (CPMV) has become one of the most intensely studied plant viruses. Research in the past 15 to 20 years has shifted from studying the underlying genetics and structure of the virus to focusing on ways in which it can be exploited in biotechnology. This work led first to the use of virus particles to present peptides, then to the creation of a variety of replicating virus vectors and finally to the development of a highly efficient protein expression system that does not require viral replication. The circle has been completed by the use of the latter system to create empty particles for peptide presentation and other novel uses. The history of CPMV in biotechnology can be likened to an Ouroborus, an ancient symbol depicting a snake or dragon swallowing its own tail, thus forming a circle.

Processing of the tobacco etch virus 49K protease requires autoproteolysis

The final products encoded by the tobacco etch virus genome arise by proteolytic cleavage of a single large polyprotein precursor. Processing of the polyprotein at several sites requires the activity of a viral protease of 49,000 molecular weight (49K). We have examined the excision of the 49K protease from polyproteins translated from defined RNA transcripts. Polyproteins containing an intact 49K protein were efficiently processed after synthesis in a rabbit reticulocyte lysate to yield the 49K product. Introduction of a single amino acid substitution (cysteine to alanine) at the putative active site of the 49K protease abolished processing, indicating that the protease was excised from the polyprotein via an autocatalytic mechanism. Release of the 49K protease was determined to require autoproteolysis, since synthetic polyproteins which contained either or both 49K cleavage sites were processed poorly, if at all, in trans reactions. Protein microsequence analysis revealed that processing in vitro occurred between a glutamine-glycine dipeptide to generate the 49K amino terminus.

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.

Translation of papaya ringspot virus RNA in vitro: detection of a possible polyprotein that is processed for capsid protein, cylindrical-inclusion protein, and amorphous-inclusion protein

The genomic RNA of papaya ringspot virus (PRV), a member of the potyvirus group, was translated in a rabbit reticulocyte cell-free system as an approach to determining the translation strategy of the virus. The RNA directed synthesis of more than 20 distinct polypeptides ranging from apparent molecular weight of 26,000 (26K) to 220K. Antiserum to PRV capsid protein (CP) reacted with a subset of these polypeptides, including a 36K protein that comigrated with PRV CP during electrophoresis. Immunoprecipitation with antiserum to PRV cylindrical-inclusion protein (CIP) defined another set of polypeptides including 70K, 108K, 205K, and 220K proteins as major precipitates. The 70K protein comigrated with authentic CIP, and the 205K and 220K proteins were related to both CP and CIP. Immunoprecipitation with antiserum to PRV amorphous-inclusion protein (AIP) defined a unique set of polypeptides which contained a 112K protein as the major precipitate and 51K, 65K, and 86K proteins as minor precipitates. The 51K protein comigrated with authentic AIR A major product of 330K was observed when translation was done without the reducing agent, dithiothreitol. Immunological analyses and kinetic studies indicated that the 330K protein zone was related to the presumed CP, CIP, and AIP zones and 330K possibly is the common precursor for these viral proteins. The presence of a polyprotein of Mr corresponding to the entire coding capacity of the genomic RNA and its likely precursor relationship to the other polypeptides suggest that proteolytic processing is involved in the translation of PRV RNA.

Nonstructural alfalfa mosaic virus RNA-coded proteins present in tobacco leaf tissue

The proteins synthesized under the direction of alfalfa mosaic virus RNAS in tobacco leaves have been examined under conditions of suppressed host protein synthesis. Besides the coat protein we could detect a 22K (K = apparent molecular weight in thousands), a 35K, and a set of 54K proteins. The 22K protein is serologically related to the coat protein. The 35K protein comigrated with the 35K protein whose synthesis is directed by RNA 3 in vitro The 54K proteins are serologically related to the 35K protein produced in vitro. Readthrough products of the 35K protein cistron into the coat protein cistron have been found previously in wheat germ extracts programmed with RNA 3. Two of these proteins comigrate with the 54K proteins synthesized in vivo. Since the 35K and the coat protein cistrons are read in different reading frames the formation of readthrough products is puzzling. In viruses with a tripartite genome the subgenomic mRNA for coat protein, RNA 4, is not known to be replicated as a separate genome entity. This might indicate that proteins synthesized by readthrough into the coat protein cistron play an essential role during replication, especially in the earliest phases.

Lucerne transient streak virus RNA and its translation in rabbit reticulocyte lysate and wheat germ extract

Two abundant, encapsidated RNAs of lucerne transient streak virus (LTSV) are the 1.5 x 10(6) molecular weight (Mr) linear RNA-1 and both circular (RNA-2) and linear (RNA-3) forms of a 0.15 x 10(6) Mr viroid-like RNA. Two additional discrete minor RNAs, Mr 0.35 x 10(6) and 0.07 x 10(6), and a heterogeneous mixture of RNAs in the Mr range 0.05 to 1.0 x 10(6) are reported. Principal polypeptides translated from unfractionated LTSV RNA in rabbit reticulocyte lysate were of Mr 105,000 (p105), 78,000 (p78), and 33,000 (p33), the last not easily detected after translation in wheat germ extracts. All apparently are encoded in RNA-1. However, p33, which was precipitated by antibody of LTSV particles and presumably is the major capsid protein, was more readily translated from a smaller, most likely the Mr 0.35 x 10(6), RNA. Partial proteolysis and other tests indicate that p105 has a carboxyl terminal extension of p78 amino acid sequences and that neither shares sequences with p33. No translation products were attributed to RNA-2, RNA-3 or the Mr 0.07 x 10(6) RNA.

Characterization of a protein from Rice tungro spherical virus with serine proteinase-like activity

The RNA genome of Rice tungro spherical virus (RTSV) is predicted to be expressed as a large polyprotein precursor (Shen et al., Virology 193, 621-630, 1993 ). The polyprotein is processed by at least one virus-encoded protease located adjacent to the C-terminal putative RNA polymerase which shows sequence similarity to viral serine-like proteases. The catalytic activity of this protease was explored using in vitro transcription/translation systems. Besides acting in cis, the protease had activity in trans on precursors containing regions of the 3' half of the polyprotein but did not process a substrate consisting of a precursor of the coat proteins. The substitution mutation of Asp(2735) of the RTSV polyprotein had no effect on proteolysis; however, His(2680), Glu(2717), Cys(2811) and His(2830) proved to be essential for catalytic activity and could constitute the catalytic centre and/or substrate-binding pocket of the RTSV 3C-like protease.

Rice tungro spherical virus polyprotein processing: identification of a virus-encoded protease and mutational analysis of putative cleavage sites

Rice tungro spherical virus encodes a large polyprotein containing motifs with sequence similarity to viral serine-like proteases and RNA polymerases. Polyclonal antisera raised against domains of the putative protease and polymerase in fusion with glutathione S-transferase detected a protein of about 35 kDa and, in very low amounts, a protein of about 70 kDa, respectively, in extracts from infected plants. In in vitro transcription/translation systems and in Escherichia coli we demonstrated a proteolytic activity in the C-terminal region of the polyprotein. This protease rapidly cleaved its polyprotein precursors in vitro. Mutating a potential cleavage site located N-terminal to the protease domain, Gln2526-Asp2527, diminished processing. The transversion mutation at the putative C-terminal cleavage site of the protease, at Gln2852-Ala2853, led to a delayed and partial processing.

A multiple alignment of the capsid protein sequences of nepoviruses and comoviruses suggests a common structure

The amino acid sequences of the regions encoding the structural proteins of eleven nepoviruses and five comoviruses, two genera of the family Comoviridae, have been aligned. The properties predicted by computer analysis (three-dimensional-3D-structure, hydrophobicity) are also correlated along this alignment, and aligned to the experimentally determined 3D structure of two comoviruses. It can thus be assumed that the 3D structure of the unique nepovirus coat protein matches that of the bipartite protomer found in the comovirus particles. In this model, the spatial locations of two amino-acid motifs characteristic of nepoviruses are in close vicinity, at the external surface of the virion. The coat proteins of nepoviruses and comoviruses may thus share a common evolutionary origin. A phylogenetic analysis was made using the multiple alignment, allowing a better understanding of the molecular relationships between these two groups of viruses.

Expression of virus-encoded proteinases: functional and structural similarities with cellular enzymes

Many viruses express their genome, or part of their genome, initially as a polyprotein precursor that undergoes proteolytic processing. Molecular genetic analyses of viral gene expression have revealed that many of these processing events are mediated by virus-encoded proteinases. Biochemical activity studies and structural analyses of these viral enzymes reveal that they have remarkable similarities to cellular proteinases. However, the viral proteinases have evolved unique features that permit them to function in a cellular environment. In this article, the current status of plant and animal virus proteinases is described along with their role in the viral replication cycle. The reactions catalyzed by viral proteinases are not simple enzyme-substrate interactions; rather, the processing steps are highly regulated, are coordinated with other viral processes, and frequently involve the participation of other factors.

On the relationship between X-bodies and symptom development in plants infected with different tobamoviruses

The relationship between systemic mosaic symptoms and the occurrence of viral 126-kDa protein in X-bodies was studied in tobacco infected with the tobacco mild green mosaic virus (TMGMV) strains U2, U5, and ribgrass mosaic virus (RMV) strain HR, and in other plant species infected with tobacco mosaic virus (TMV) strain W U 1. Strains U2, U5, and HR coded for proteins of 126, 126, and 130 kDa, respectively, but these were not recognized by antisera against the corresponding protein from W U 1. Only the HR 130-kDa protein reacted with an antiserum raised against a peptide of amino acids 849-863 from the sequence of W U 1. Electron microscopic analysis established the presence of virus clusters in the cytoplasm, as well as in chloroplasts, in leaf tissue infected with U 2 or U 5, and adjacent to nuclei and chloroplasts in scattered cells infected with HR. X-bodies were not detected after infection with any of these strains, but were large and adjacent to nuclei in W U 1-infected tomato displaying severe mosaic symptoms. Large X-bodies were detected near nuclei in W U 1-infected tomato displaying severe mosaic symptoms, but none were detected after infection of tobacco with any of the other tobamoviruses. The induction of X-bodies appears to be characteristic of some tobamovirus only and, at best, can only be associated with, rather than causative of, the severity of symptoms induced by those viruses.

Mutational analysis of AUG codons of cowpea mosaic virus M RNA

The involvement of the AUG codons at positions 115, 161, 512 and 524 in translation and infectivity of cowpea mosaic virus M RNA was studied. Mutations were introduced in each of these codons in a full length cDNA clone of M RNA and the effect of the mutations was examined by translation from in vitro transcripts of these mutant cDNAs in rabbit reticulocyte lysates and by checking the replication of these transcripts in the presence of B RNA in cowpea protoplasts and plants. It was found that AUG115, at the beginning of an open reading frame (ORF) for a putative 2-kDa protein, can be used in vitro to initiate translation, but mutation of this AUG codon in the M RNA does not affect the ability of the virus to infect cowpea plants. AUG161, located at the beginning of the large ORF, was shown to be essential for expression of the large 105-kDa polyprotein and for replication of M RNA. Translation of the second 95-kDa polyprotein was found to start at AUG512. Upon mutation of this AUG codon efficient initiation of translation occurred at AUG524. Results with M RNAs that lack AUG512 and/or 524 indicate that an intact 95-kDa polyprotein is not required for replication of M RNA but that this protein has an essential function in cell-to-cell movement of the virus.

A regulatory role for the 32K protein in proteolytic processing of cowpea mosaic virus polyproteins

We have studied the regulation of proteolytic processing of the polyproteins encoded by cowpea mosaic virus M-RNA and B-RNA. For that purpose mutations were introduced in full-length cDNA clones of these RNAs. RNA transcripts were translated in rabbit reticulocyte lysate and the effect of mutations on the processing was analysed. These studies revealed that the 32K protein is released from the 200K B-polyprotein by an intramolecular cleavage and remains associated with the 170K protein, probably by interaction with the 58K domain of the 170K protein. In this complex the conformation of the 170K protein is such that further cleavages are very slow. This complex carries out the processing of the Gln/Met site in the M-polyprotein. The 170K protein produced by a B-RNA mutant that lacks the 32K coding region was efficiently processed into 110K, 87K, 84K, 60K, 58K and 24K cleavage products. Thus, the 32K protein regulates the B-polyprotein processing by slowing it down and, on the other hand, enhances trans cleavage of M-polyproteins at a Gln/Met site.

The nucleotide sequence of apple stem grooving capillovirus genome

The complete nucleotide sequence of apple stem grooving virus (ASGV) genome has been determined. The genome is 6496 nucleotides in length excluding a 3'-terminal poly(A) tail and contains two overlapping open reading frames (ORFs). ORF1 begins at nucleotide position 37 and is terminated at position 6341, encoding a protein with a molecular weight of 241 kDa. ORF2, which is in a different reading frame within ORF1, begins at position 4788 and can encode a 36-kDa protein. The 241-kDa protein contains two consensus sequences associated with the RNA-dependent RNA polymerase and the NTP-binding helicase. Comparisons of amino acid sequences around these conserved motifs with other RNA viruses revealed that ASGV has extensive similarities with apple chlorotic leaf spot, tymo-, carla-, and potexviruses, and is a member of the sindbis-like supergroup. ASGV coat protein is found to be located in the C-terminal region of the 241-kDa polyprotein. The 36-kDa protein encoded by ORF2 contains the consensus sequence Gly-Asp-Ser-Gly found in the active site of several cellular and viral serine proteases.

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.

Nucleotide sequence and genetic map of cowpea severe mosaic virus RNA 2 and comparisons with RNA 2 of other comoviruses

We report the nucleotide sequence of cowpea severe mosaic comovirus (CPSMV) genomic RNA 2. The molecule is composed of 3732 nucleotide (nt) residues, exclusive of the polyadenylate at the 3' end. Only one of the six reading frame registers has a long open reading frame, from nt 255 to nt 3260 in the polarity of encapsidated RNA and corresponding to a polyprotein of 1002 amino acid residues (aa). As has been reported for other comoviruses, a second in-frame AUG, at nt position 531, apparently also initiates translation, at least in vitro. Multiple alignments of the deduced CPSMV polyprotein aa sequence with those of bean pod mottle comovirus (BPMV), cowpea mosaic comovirus (CPMV), and red clover mottle comovirus (RCMV) were consistent with a similar size for each of the three genes: the putative movement protein, beginning at the second in-frame AUG, the large coat protein (L), and the small coat protein. Identical nucleotide sequences in the terminal noncoding regions of RNA 2 of the four viruses are limited to 9 nt at the 5' end and the 3' polyadenylate. However, extensive similarities in sequence and potential structure were found. For all three genes and the 5' untranslated region, CPSMV and BPMV are more similar to each other than either is to CPMV or RCMV, the last two being similar to each other. Observed similarities predict that both cleavage sites in the CPSMV RNA 2 polyprotein are at glutamine-serine dipeptides. A sequence of 16 aa at the amino terminus of L, determined by automated Edman degradation, matched a region of the deduced aa sequence in the polyprotein and is consistent with cleavage at the predicted glutamine-serine dipeptide.

Translation of potato virus S RNA in vitro: evidence of protein processing

RNA from potato virus S (PVS), a member of the carlavirus group, was translated in vitro in rabbit reticulocyte lysate. Time-course experiments revealed the largest product of Mr 190 kD, decreasing in intensity after 60-min incubations, correlating with the accumulation of a 150-kD peptide. This apparent processing could be blocked by the addition of the amino-acid analogues p-fluorophenylalanine and L-canavanine for phenylalanine and arginine, respectively. L-canavanine also appeared to specifically reduce the quantity of PVS (34 kD) coat protein, concomitant with the synthesis of a 36-kD peptide. Sucrose gradient-fractionated genomic RNA directed the synthesis of predominantly 190-kD peptides that appeared not to be processed in the absence of small molecular weight (subgenomic) RNA products.

Mutational analysis of the putative catalytic triad of the cowpea mosaic virus 24K protease

To investigate the mechanism of action of the cowpea mosaic virus (CPMV) 24K protease, a full-length cDNA clone of bottom component (B) RNA has been constructed from which RNA can be transcribed in vitro using T7 RNA polymerase. Translation of the resulting RNA in rabbit reticulocyte lysate leads to the synthesis of a 200 kDa product (the 200K protein) which cleaves itself in a manner identical to that of the product translated from B RNA isolated from virions. Site-directed mutagenesis of the full-length clone was used to examine the effects of altering individual amino acids in the 24K protease on its activity. The results obtained are consistent with the prediction that the 24K protease is structurally similar to the trypsin-like family of serine proteases and suggest that His40, Glu76, and Cys166 comprise the active site. Substitution of Cys166 by a serine residue results in an enzyme with reduced catalytic activity.

Cell-free translation of American hop latent virus RNA

The RNA of American hop latent virus (AHLV) has a molecular size of 7.7 kb measured in agarose gels. Translation products of AHLV RNA in rabbit reticulocyte and wheat-germ cell-free systems ranged in size up to 200 kD. Time-course experiments indicated that a 36 kD peptide, immunoprecipitated by antivirion sera, was synthesized early followed by the sequential appearance of peptides of increasing Mr. An excess of the amino-acid analogue L-canavanine for arginine specifically reduced the quantity of the 36 kD peptide and induced synthesis of a 38-kD peptide in both rabbit reticulocyte and wheat germ. Translation products were not altered by the addition of a reducing agent, and no product appeared to be produced due to limitation of tRNA species or by readthrough. Synthesis of AHLV RNA-directed peptides was blocked by the cap analogue m7G5'ppp5'G, suggesting the presence of a cap structure at the 5' terminus.

The ATP requirement for initiation of eukaryotic translation varies according to the mRNA species

The requirement for ATP for initiation of eukaryotic mRNA translation was tested using gel-filtered rabbit reticulocyte lysates incubated with labelled Met-tRNAfMet and exogenous RNA templates, and assaying the formation of labelled 80S initiation complexes in the presence of GTP, or labelled 40S initiation complexes in the presence of a non-hydrolysable analogue of GTP. Initiation complex formation on globin mRNA, or on capped viral RNAs such as papaya mosaic virus RNA and tobacco mosaic virus RNA, was strongly stimulated by ATP. In contrast, initiation complex formation on (uncapped) encephalomyocarditis virus RNA was uninfluenced by the presence or absence of ATP, which may be correlated with the recent evidence for scanning-independent internal initiation on this viral RNA. In addition, initiation complex formation on uncapped cowpea mosaic virus RNA and on poly(A,U,G) was only slightly stimulated by ATP, much less than in the case of the capped RNAs. These results suggest that most of the ATP hydrolysed during translation initiation is consumed in cap-dependent processes, probably in unwinding the mRNA, and relatively little in the actual migration or scanning of 40S subunits along the mRNA.

Analysis of the nucleotide sequence of bean pod mottle virus middle component RNA

The complete nucleotide sequence of the middle component RNA (M RNA) of the comovirus bean pod mottle virus (BPMV) has been determined. The sequence consists of 3662 nucleotides and contains a single long open reading frame sufficient to code for a protein of 113,353 Da. The proteolytic processing sites within this protein have been identified by comparison with the known three-dimensional structure of the virion and cleavage at these sites would lead to a range of products consistent with those observed during processing of the M RNA-encoded polyproteins in vitro. We have performed computer-aided searches for reiterated sequences within BPMV M RNA which might explain why ordered RNA is visible in the electron density map of BPMV middle component particles (Chen, Z., Stauffacher, C. V., Li, Y., Schmidt, T., Bomu, W., Kamer, G., Shanks, M., Lomonossoff, G., and Johnson, J. E., 1989, Science 245, 154-159). These searches revealed both the presence of overrepresented pentameric sequences and a consensus sequence which was repeated 15 times within the RNA sequence.

Cowpea mosaic virus middle component RNA contains a sequence that allows internal binding of ribosomes and that requires eukaryotic initiation factor 4F for optimal translation

Cowpea mosaic virus (CPMV) middle component RNA (M-RNA) encodes two proteins of 105 and 95 kDa, of which translation starts at nucleotide (nt) 161 and nt 512, respectively. In vitro translation of both proteins directed by T7 transcripts of M-RNA was stimulated fourfold by eukaryotic initiation factor 4F (eIF-4F), the cap-binding protein complex. The ratio of the synthesis of both proteins after translation was not influenced by eIF-4F or by any known eIF. Part of the CPMV 5' sequence was cloned downstream of the 5' untranslated region of ornithine decarboxylase (ODC); the latter untranslated sequence has a highly stable secondary structure, preventing efficient translation of ODC. Insertion of nt 161 to 512 of CPMV M-RNA upstream of the ODC initiation codon resulted in a marked increase in ODC translation, which indicates that the CPMV sequence contains an internal ribosome-binding site. The insertion conferred stimulation by eIF-4F on ODC translation, showing that eIF-4F is able to stimulate internal initiation.

Cell-free translation of carnation latent virus RNA and analysis of virus-specific dsRNA

Carnation latent virus was shown to direct the synthesis of virus-specific polypeptides in both reticulocyte lysate and wheat germ in vitro translation systems. The L-(4,5-3H)-leucine-labeled products ranged in molecular mass from Mr 190 to 33 kD. The 33 kD product, synthesized after only 15 min incubation, was the only major polypeptide that immunoprecipitated with antiserum to CarLV. Coat-protein synthesis does not occur as a result of proteolytic processing, but may arise as a result of translation of a subgenomic RNA species. Subgenomic RNA species were not detected by Northern hybridization of CarLV cDNA to either viral RNA or total nucleic acid from systemically infected plants, although CarLV-specific dsRNA species equivalent to 1.6 and 2.1 kb were detected.

Synthesis and proteolytic processing of arabis mosaic nepovirus, cherry leaf roll nepovirus, and strawberry latent ringspot nepovirus proteins in reticulocyte lysate

The genomic RNA components of three nepoviruses, arabis mosaic (ArMV), cherry leaf roll (CLRV), and strawberry latent ringspot (SLRV), were translated in rabbit reticulocyte lysate. Each component (except the RNA-2 of CLRV) directed the synthesis of proteins that corresponded in size to their theoretical coding capacity. The RNA-1 components of all three viruses were translated to yield polyproteins of Mr 250k, which were autocatalytically processed to yield up to five cleavage products. The primary products of translation of the RNA-2 components of ArMV (Mr 115k and 105k), CLRV (Mr 165k) and SLRV (Mr 99k and 96k) were polyproteins that were stable on incubation, but which underwent proteolytic processing in the presence of the corresponding RNA-1 and its translation products. These polyproteins were immunoprecipitated using antisera to appropriate virions indicating that the RNA-2 sequences encode the coat protein cistrons.

Proteolytic origin of the 150-kilodalton protein encoded by turnip yellow mosaic virus genomic RNA

Turnip yellow mosaic virus genomic RNA codes in vitro for two overlapping proteins, 150-kilodalton (150K protein) and 206-kilodalton (206K protein) proteins. The proteolytic maturation known to affect the 206K protein has been further characterized by in vitro translation assays in a reticulocyte lysate or wheat germ extract. Cleavage is inhibited at 37 degrees C and restored when the temperature is shifted to 30 or 25 degrees C. Temperature shift experiments are used here to demonstrate that the 150K protein and the previously characterized 78K protein are the two fragments resulting from a primary cleavage phenomenon that affects the 206K protein in a cotranslational manner under usual translation conditions. This processing is prevented by several cysteine and serine proteinase inhibitors.

Analysis of sequences involved in cowpea mosaic virus RNA replication using site-specific mutants

Using a full-length cDNA clone of cowpea mosaic virus (CPMV) B-RNA from which infectious transcripts can be generated, we examined the influence of a sequence of 11 nucleotides, UUUUAUUAAAA, comprising the nucleotides 5883 to 5893 in the 3' noncoding region of B-RNA, on viral RNA replication. This sequence is not only present in B-RNA but also in M-RNA and represents the 7 nucleotides preceding the poly(A) tail and the first four A residues of the poly(A) tail. Replication of B-RNA transcripts derived from a series of mutants in this region was tested in cowpea plants and protoplasts. Only mutant transcripts with minor modifications appeared able to replicate, which indicates that the region has a function in viral RNA replication. In addition, the results suggest the existence of a hairpin loop in this region. Those transcripts with deletions which disturb the putative hairpin structure have decreased specific infectivities. Mutant transcripts reversed stepwise to the wild-type sequence during replication in plants. This observation strengthens the idea that the sequence of 11 nucleotides has a function in viral RNA replication.

Identification and subcellular localization of a putative cell-to-cell transport protein from red clover mottle virus

To investigate the mode of gene expression of red clover mottle virus (RCMV) middle component (M) RNA, we have synthesized an oligopeptide corresponding to the predicted carboxy-terminus of the RCMV counterparts of the cowpea mosaic virus (CPMV) 48K and 58K proteins. Using an antiserum raised against this synthetic oligopeptide, we have detected a 43-kDa protein in the 30,000 g pellet from extracts of RCMV-infected cowpea protoplasts. Immunogold cytochemistry further localized this protein to the plasmodesmata of RCMV-infected pea tissue. This subcellular location, taken together with other evidence, suggests that this 43-kDa protein has a role in the cell-to-cell spread of RCMV.

Inhibition of proteolytic processing of the polyproteins of cowpea mosaic virus by hemin

Cleavages of the polyproteins synthesized from cowpea mosaic virus (CPMV) B RNA and M RNA in rabbit reticulocyte lysates are inhibited by hemin. Cleavage of the CPMV B RNA-encoded 200K polyprotein and of the M RNA-encoded 60K intermediary precursor protein were most sensitive to hemin inhibition, while cleavages of other precursor proteins were less sensitive. A significant observation was that at a hemin concentration of 25 microM, but not at higher concentrations, the 60K protein was cleaved to yield the two viral capsid proteins. This cleavage reaction has not been observed in vitro previously.

Characterization of the catalytic residues of the tobacco etch virus 49-kDa proteinase

The 49-kDa proteinase of tobacco etch virus (TEV) cleaves the polyprotein derived from the TEV genomic RNA at five locations. Molecular genetic and biochemical analyses of the 49-kDa TEV proteinase were performed to test its homology to the cellular trypsin-like serine proteases. A cDNA fragment, containing the TEV 49-kDa proteinase gene and flanking sequences, was expressed in a cell-free transcription/translation system and resulted in the formation of a polyprotein precursor that underwent rapid self-processing. Site-directed mutagenesis was used to test the effect of altering individual 49-kDa amino acid residues on proteolysis. The data suggest that the catalytic triad of the TEV 49-kDa proteinase could be composed of the His234, Asp269, and Cys339. These findings are consistent with the hypothesis that the TEV 49-kDa proteinase is structurally similar to the trypsin-like family of serine proteinases with the substitution of Cys339 as the active site nucleophile. A structural model of the TEV 49-kDa proteinase proposes other virus-specific differences in the vicinity of the active site triad and substrate-binding pocket. The structure may explain the observed negligible effect of most cellular proteinase inhibitors on the activity of this viral proteinase.

Identification of the initiation codons for translation of cowpea mosaic virus middle component RNA using site-directed mutagenesis of an infectious cDNA clone

A full-length cDNA copy of CPMV M RNA has been cloned downstream of a phage lambda promoter in the plasmid pPMI. Transcripts obtained from this clone can be translated in vitro and replicated in cowpea mesophyll protoplasts in the presence of viral B RNA. We have constructed a series of site-directed mutants of this clone to investigate the mechanism of translation of CPMV M RNA. The results obtained confirm that the AUG at position 161 is used to direct the synthesis of a 105K protein in vitro and the detection of a 58K protein in infected cowpea protoplasts suggests that it is also used in vivo. The synthesis of the 95K protein can be initiated from either of the AUGs at positions 512 and 524, though synthesis of this protein does not appear to be essential for CPMV replication in protoplasts.

A comparative study on the cell-free translation of the genomic RNAs of two aphid picorna-like viruses

The genomic RNAs of aphid lethal paralysis virus (ALPV) and Rhopalosiphum padi virus (RhPV)--two distinct picorna-like viruses found in aphids [Williamson et al. (1988) J Gen Virol 69: 787-795]--were both efficiently translated in rabbit reticulocyte lysates. ALPV RNA was translated into primary products with molecular weights ranging from 92 kDa to 170 kDa. These underwent time-dependent post-translational cleavage to produce smaller polypeptides including some with molecular weights comparable to those of the viral structural proteins. A 92 kDa polypeptide as well as smaller proteins were immunoprecipitated with capsid protein antisera, indicating the presence of at least one large capsid subunit protein precursor. RhPV RNA was translated into products of molecular weights ranging from 45 kDa to 175 kDa. There was no evidence for time-dependent post-translation cleavage of RhPV translation products. However, a 60 kDa polypeptide was precipitated with antiserum to RhPV virions, indicating that at least one capsid protein of RhPV is derived by proteolysis of a precursor protein, like those of ALPV and most other picornaviruses.

Association of viral 126 kDa protein-containing X-bodies with nuclei in mosaic-diseased tobacco leaves

During the development of systemic mosaic symptoms in tobacco mosaic virus (TMV)-infected tobacco, the viral non-structural 126-kDa-protein was present among the chromatin-associated proteins in fractionated leaf homogenates [Van Telgen HJ et al. (1984) Virology 143: 612-616]. Using an antiserum raised against a fusion protein of beta-galactosidase and part of the 126-kDa-protein of TMV, this viral protein was detected by immunoelectron microscopy in X-bodies in infected tissue. No labelling of nuclei was apparent. However, in embedded purified nuclear preparations from systemically infected leaves amorphous structures, most likely X-bodies, were present and specifically labelled. In contrast, using antibodies against tobacco histones, only nuclei were labelled. Antibodies against viral coat protein labelled crystalline virus inclusions in the cytoplasm and did not react with nuclei. Light microscopic analysis indicated that X-bodies were almost always associated with nuclei. Thus, the presence of X-bodies in nuclear preparations appeared to result from adherence of the X-bodies to the nuclei.

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.

Identification of putative polymerase gene product in cells infected with murine coronavirus A59

The virion RNA of mouse hepatitis virus, strain A59 (MHV-A59) is believed to be the mRNA for the viral RNA-dependent RNA polymerase. The cell-free translation of virion RNA results in the synthesis of two predominant products p220 and p28 (M. R. Denison and S. Perlman, 1986, J. Virol. 60, 12-18). p28 is a basic protein and is readily detected by two-dimensional gel electrophoresis. When infected cells and isolated virions were assayed for this protein by two-dimensional gel electrophoresis, p28 could be detected in infected cells labeled at late times after infection, but not at early times or in purified virions. p28 represents the first protein product of the putative coronavirus polymerase gene to be identified in infected cells.

Characterization of a virus-specific proteolytic activity processing the gag precursor of the simian sarcoma-associated virus

The proteolytic processing of the gag precursor polypeptide pr65gag of simian sarcoma-associated virus (SSAV) has been studied in vivo and in vitro. In SSAV-infected cells (i.e., in vivo) proteins of 52 and 38 kDa and the viral protein p30 could be immunoprecipitated with anti-p30 serum. This cleavage pattern is only in part imitated by in vitro cleavage of the isolated pr65gag with avian myeloblastosis virus (AMV) protease p15. However, in vitro incubation of isolated pr65gag with detergent-disrupted SSAV particles generated products identical in size to those found in vivo, i.e., proteins of 52 and 38 kDa and p30. The extent of cleavage is dependent on the concentration of the disrupted virions added to the incubation mixture. Studies with protease inhibitors suggest that the SSAV enzyme is a serine-type protease like that of other mammalian retroviruses and unlike the protease of avian viruses. The SSAV protease activity eluted from a molecular sieve column in a range of about 10-15 kDa reflecting the molecular weight of the murine leukemia virus (MuLV) protease (Mr = 13.5K). Thus, it appears that there is a close similarity between the proteolytic enzymes present in different mammalian retroviruses such as MuLV and SSAV.

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.

Translation and processing of mouse hepatitis virus virion RNA in a cell-free system

The first event after infection with mouse hepatitis virus strain A59 (MHV-A59) is presumed to be the synthesis of an RNA-dependent RNA polymerase from the input genomic RNA. The synthesis and processing of this putative polymerase protein was studied in a cell-free translation system utilizing 60S RNA from MHV-A59 virions. The polypeptide products of this reaction included two major species of 220 and 28 kilodaltons. Kinetics experiments indicated that both p220 and p28 appeared after 60 min of incubation and that protein p28 was synthesized initially as the N-terminal portion of a larger precursor protein. When the cell-free translation products were labeled with N-formyl[35S]methionyl-tRNAi, p28 was the predominant radioactive product, confirming its N-terminal location within a precursor protein. Translation in the presence of the protease inhibitors leupeptin and ZnCl2 resulted in the disappearance of p28 and p220 and the appearance of a new protein, p250. This product, which approached the maximal size predicted for a protein synthesized from genomic RNA, was not routinely detected in the absence of inhibitors even under conditions which optimized the translation reaction for elongation of proteins. Subsequent chelation of ZnCl2 resulted in the partial cleavage of the precursor protein and the reappearance of p28. One-dimensional peptide mapping with Staphylococcus aureus V-8 protease confirmed the precursor-product relationship of p250 and p28. The results show that MHV virion RNA, like many other viral RNAs, is translated into a large polyprotein, which is cleaved soon after synthesis into smaller, presumably functional proteins. This is in marked contrast to the synthesis of other MHV proteins, in which minimal proteolytic processing occurs.

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.

A detailed kinetic analysis of the in vitro synthesis and processing of encephalomyocarditis virus products

Translation of encephalomyocarditis virus RNA in rabbit reticulocyte lysates has been used to analyse the pathway of proteolytic processing of the primary translation products. A minimum of two distinct proteases is required to account for the results: one for the excision of the capsid precursor protein, A1, from the nascent polyprotein, and the other for all other cleavages including cleavage at the F/C junction. The excision of A1 is an extremely rapid reaction which occurs as soon as the cleavage site has been synthesised and is resistant to all the proteolytic inhibitors tested and to high temperature, characteristics which are more consistent with an intramolecular cleavage catalysed by a virus-coded protease than cleavage by an endogenous reticulocyte protease. Once excised, A1 remains stable until translation has reached the middle of the region of the genome coding for C, at which time a number of events occur in rapid succession: F is excised in its mature form probably via an intramolecular cleavage; a proteolytic activity capable of secondary processing of A1 to A, B, D1, alpha, gamma and epsilon appears; and a polypeptide of molecular weight about 32,000 appears. This protein (p32) originates from the N-terminal portion of C, and maps in the same position on the genome as p22, the protein previously identified as the virus-coded protease. Polypeptide p32 is derived from C by a single step cleavage generating E as the other product, a processing pathway at least as important, if not more important than the step-wise route via D as an intermediate. Since p32 first appeared at the same time as the start of secondary processing, whilst p22 was first detected much later, it is argued that at least the early stages of processing of the capsid precursor must have been carried out by p32 rather than p22.