The genomic sequence of cowpea aphid-borne mosaic virus and its similarities with other potyviruses.

The genomic sequence of a Zimbabwe isolate of Cowpea aphid-borne mosaic virus (CABMV-Z) was determined by sequencing overlapping viral cDNA clones generated by RT-PCR using degenerate and/or specific primers. The sequence is 9465 nucleotides in length excluding the 3' terminal poly (A) tail and contains a single open reading frame (ORF) of 9159 nucleotides encoding a large polyprotein of 3,053 amino acids and predicted Mr of 348. The size of the genome and the encoded polyprotein is in agreement with other potyviruses and contains nine putative proteolytic cleavage sites and motifs conserved in homologous proteins of other potyviruses. The P1 and P3 were the most variable proteins while CI, NIb and CP were the most conserved.

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.

Studies on the movement of cowpea mosaic virus using the jellyfish green fluorescent protein.

The jellyfish green fluorescent protein (GFP) coding sequence was used to replace the coat protein (CP) genes in a full-length cDNA clone of CPMV RNA-2. Transcripts of this construct were replicated in the presence of RNA-1 in cowpea protoplasts, and GFP expression could be readily detected by fluorescent microscopy. It was not possible to infect cowpea plants with these transcripts, but combined with a mutant RNA-2, in which the 48-kDa movement protein (MP) gene has been deleted infection did occur. With this tripartite virus (CPMV-TRI) green fluorescent spots were visible under UV light on the inoculated leaf after 3 days and a few days later on the higher leaves. These results show that the polyproteins encoded by RNA-2 do not possess an essential function in the virus infection cycle and that there is, contrary to what we have found so far for the proteins encoded by RNA-1, no need for a tight regulation of the amounts of MP and CPs produced in a cell. Subsequently, the GFP gene was introduced between the MP and CP genes of RNA-2 utilizing artificial proteolytic processing sites for the viral proteinase. This CPMV-GFP was highly infectious on cowpea plants and the green fluorescent spots that developed on the inoculated leaves were larger and brighter than those produced by CPMV-TRI described above. When cowpea plants were inoculated with CPMV RNA-1 and RNA-2 mutants containing the GFP gene but lacking the CP or MP genes, only single fluorescent epidermal cells were detected between 2 and 6 days postinoculation. This experiment clearly shows that both the capsid proteins and the MP are absolutely required for cell-to-cell movement.

Capsid proteins of cowpea mosaic virus transiently expressed in protoplasts form virus-like particles.

The coding regions for cowpea mosaic virus (CPMV) capsid proteins VP37 and VP23 were introduced separately into a transient plant expression vector containing an enhanced CaMV 358 promoter. Significant expression of either capsid protein was observed only in protoplasts transfected simultaneously with both constructs. Immunosorbent electron microscopy revealed the presence of virus-like particles in extracts of these protoplasts. An extract of protoplasts transfected with both constructs together with RNA-1 was able to initiate a new infection, showing that the two capsid proteins of CPMV can form functional particles containing RNA-1 and that the 60-kDa capsid precursor is not essential for this process.

Accessibility and environment probing using cysteine residues introduced along the putative transmembrane domain of the major coat protein of bacteriophage M13.

The major coat protein of the filamentous bacteriophage M13 is located in the inner membrane of host cell Escherichia coli prior to assembly into virions. To identify the transmembrane domain of the coat protein, we have introduced unique cysteine residues along the putative transmembrane domain at position 25, 31, 33, 36, 38, 46, 47, 49, or 50. The mutant major coat protein was solubilized by membrane-mimicking detergents or reconstituted into mixed bilayers of phospholipids. Information about the environmental polarity was deduced from the wavelength of maximum emission, using N-[[(iodoacetyl)-amino)ethyl]-1-sulfonaphthylamine (IAEDANS) attached to the SH groups of the cysteines as a fluorescent probe. Additional information was obtained by determining the accessibility of AEDANS for the fluorescence quencher molecules acrylamide and 5-doxylstearic acid, and the reactivity of the cysteine's sulfhydryl group toward 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB). Our data suggest transmembrane boundaries close to residue 25 and 46, with residue 25 inside the hydrophobic part of the membrane in very close proximity to the membrane-water interface and residue 46 located at the membrane-water interface. Domains of the mutant coat protein which are packed or coated by cholate molecules and various other detergents [except for sodium dodecyl sulfate (SDS)] are at least similarly packed by phospholipid molecules in bilayers. SDS is a good solubilizing detergent but badly mimics the typical nature of a membrane structure. The overall results are interpreted with respect to the established conformation of the coat protein and its membrane anchoring mechanism.

The cowpea mosaic virus RNA 1-encoded 112 kDa protein may function as a VPg precursor in vivo.

Processing of the 112 kDa ('112K') protein encoded by cowpea mosaic virus RNA 1 was examined in cowpea mesophyll protoplasts using a transient expression system. Cleavage of the 112K protein occurred via two alternative pathways either into VPg and 110K (24K + 87K) or into 26K (VPg + 24K) and 87K proteins. The 26K protein can be further cleaved into VPg and 24K proteins. The results support a model in which the 112K protein functions as the precursor of VPg during initiation of replication.

The NTP-binding motif in cowpea mosaic virus B polyprotein is essential for viral replication.

We have assessed the functional importance of the NTP-binding motif (NTBM) in the cowpea mosaic virus (CPMV) B-RNA-encoded 58K domain by changing two conserved amino acids within the consensus A and B sites (GKSRTGK500S and MDD545, respectively). Both Lys-500 to Thr and Asp-545 to Pro substitutions are lethal as mutant B-RNAs were no longer replicated in cowpea protoplasts. Transiently produced mutant proteins were not able to support trans-replication of CPMV M-RNA in cowpea protoplasts in contrast to transiently produced wild-type B proteins. Therefore loss of viral RNA synthesis was a result of a protein defect rather than an RNA template defect. Mutant B polyproteins were correctly processed in vitro and in vivo and the regulatory function of the 32K protein on processing of B proteins was not affected by these mutations. Since regulation of processing by the 32K protein depends on interaction with the 58K domain, the mutations in the NTBM apparently do not interfere with this interaction. The Asp-545 to Pro substitution left intact the binding properties of the 84K precursor of the 58K protein, with respect to ATP-agarose, whereas the Lys-500 to Thr substitution decreased the binding capacity of the 84K protein, suggesting that the Lys-500 residue is directly involved in ATP binding. The Lys-500 to Thr substitution in the 58K domain resulted in an altered distribution of viral proteins, which failed to aggregate into large cytopathic structures as observed in protoplasts infected with wild-type B-RNA. However viral proteins containing the Asp-545 to Pro substitution showed a normal distribution in protoplasts.

Replication and translation of cowpea mosaic virus RNAs are tightly linked.

The genome of cowpea mosaic virus (CPMV) is divided among two positive strand RNA molecules. B-RNA is able to replicate independently from M-RNA in cowpea protoplasts. Replication of mutant B-transcripts could not be supported by co-inoculated wild-type B-RNA, indicating that B-RNA cannot be efficiently replicated in trans. Hence replication of a B-RNA molecule is tightly linked to its translation and/or at least one of the replicative proteins functions in cis only. Remarkably also for efficient replication of M-RNA one of its translation products was found to be required in cis. This 58K protein possibly helps in directing the B-RNA-encoded replication complex to the M-RNA. In order to identify the viral polymerase the CPMV B-RNA-specific proteins have been produced individually in cowpea protoplasts using CaMV 35S promoter based expression vectors. Only protoplasts transfected with a vector containing the 200K coding sequence were able to support replication of co-transfected M-RNA. Despite this, CPMV-specific RNA polymerase activity could not be detected in extracts of these protoplasts using a poly(A)/oligo(U) assay. These results indicate that, in contrast to the poliovirus polymerase, the CPMV polymerase is not able to accept oligo(U) as a primer and in addition support the concept that translation and replication are linked.

Adaptation of positive-strand RNA viruses to plants.

The vast majority of positive-strand RNA viruses (more than 500 species) are adapted to infection of plant hosts. Genome sequence comparisons of these plant RNA viruses have revealed that most of them are genetically related to animal cell-infecting counterparts; this led to the concept of "superfamilies". Comparison of genetic maps of representative plant and animal viruses belonging to the same superfamily (e.g. cowpea mosaic virus [CPMV] versus picornaviruses and tobacco mosaic virus versus alphaviruses) have revealed genes in the plant viral genomes that appear to be essential adaptations needed for successful invasion and spread through their plant hosts. The best studied example represents the "movement protein" gene that is actively involved in cell-to-cell spread of plant viruses, thereby playing a key role in virulence and pathogenesis. In this paper the host adaptations of a number of plant viruses will be discussed, with special emphasis on the cell-to-cell movement mechanism of comovirus CPMV.

Protoplasts transiently expressing the 200K coding sequence of cowpea mosaic virus B-RNA support replication of M-RNA.

In order to identify the viral polymerase involved in cowpea mosaic virus (CPMV) RNA replication the 87K, 110K and 170K proteins as well as the complete 200K polyprotein of CPMV B-RNA have been produced in cowpea protoplasts, using expression vectors based on the 35S promoter of cauliflower mosaic virus. CPMV-specific proteins were obtained that were indistinguishable from proteins found in CPMV-infected protoplasts. Proteolytic processing of precursor proteins synthesized from the expression vectors proved that the 24K protease contained within these proteins is active. Moreover, it was established that protoplasts transfected with the expression vector containing the entire 200K coding sequence, but not those transfected with vectors containing the 170K, 110K or 87K coding sequences, were able to support replication of co-inoculated M-RNA. Despite the ability to support replication of M-RNA for protoplasts transiently expressing the 200K coding region, CPMV-specific RNA polymerase activity dependent on exogenous added template RNA could not be detected in extracts of these protoplasts in assays using poly(A).oligo(U) or other template/primer combinations. In contrast, extracts of protoplasts in which poliovirus polymerase was produced exhibited RNA polymerase activity in such assays. These results indicate that the CPMV polymerase, unlike the poliovirus polymerase, is not able to use oligo(U) as a primer or cannot function on exogenous template and primer RNA.

Cis- and trans-acting elements in cowpea mosaic virus RNA replication.

Cowpea mosaic virus (CPMV) B-RNA encodes the viral proteins required for viral RNA replication while M-RNA does so for the capsid proteins and functions required in cell-to-cell movement of the virus. Accordingly, B-RNA can replicate by itself, whereas M-RNA can only replicate in the presence of B-RNA. We have made heterologous sequence insertions at different positions in the open reading frame of B-RNA, leaving the 5' and 3' non-coding ends intact. None of these mutant B-RNAs were able to replicate. Furthermore, it was not possible to support replication of these mutant B-RNAs by co-inoculating wild-type B-RNA as a helper, indicating that B-RNA can not be replicated in trans. In contrast, replication of M-RNA must occur in trans, as the viral replicative proteins are encoded by B-RNA. Mutant M-RNA transcripts containing 5' and 3' non-coding regions of B-RNA are still efficiently replicated in protoplasts if co-inoculated with B-RNA, indicating that in cis or in trans replication of the CPMV RNAs is not primarily determined by the non-coding regions. Remarkably, for replication of M-RNA, the N-terminal domain of the 58K protein encoded by M-RNA was found to be required.

The involvement of cowpea mosaic virus M RNA-encoded proteins in tubule formation.

On the surface of cowpea protoplasts inoculated with cowpea mosaic virus (CPMV), tubular structures containing virus particles have been found. Such tubular structures are thought to be involved in cell-to-cell movement of CPMV in cowpea plants. To study the involvement of the 58K/48K and capsid proteins of CPMV in the formation of the tubular structures, mutations were introduced into M cDNA clones from which infectious transcripts could be derived. No tubules were found on protoplasts inoculated with a mutant that fails to produce the 48K protein nor with a mutant that has a deletion in the 48K coding region, suggesting that the 48K protein is essential for this process. However, a possible role of the 58K protein in tubule formation could not be excluded. A mutant that fails to produce the capsid proteins did produce tubules and therefore the capsid proteins are not involved in the formation of the tubular structures. Electron microscopic analysis revealed that the tubules produced by this mutant are, apart from the absence of virus particles, morphologically identical to the tubules formed by the wild-type virus.

The cowpea mosaic virus M RNA-encoded 48-kilodalton protein is responsible for induction of tubular structures in protoplasts.

Tubular structures extending from plasmodesmata in cowpea mosaic virus (CPMV)-infected tissue have been implicated to play an important role in cell-to-cell movement of this virus. Using a cauliflower mosaic virus 35S promoter-based transient expression vector, we show that expression of only the CPMV M RNA-encoded 48-kDa protein (48K protein) in cowpea protoplasts is sufficient to induce these structures. Strikingly, expression of the 48K protein in protoplasts from a number of nonhost plant species, such as barley, Arabidopsis thaliana, and carrot, also resulted in tubular structure formation. Thus, it is not likely that the viral 48K protein, though playing a key role in cell-to-cell movement of CPMV, has a role in determining the host range of CPMV.

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.

The sequence between nucleotides 161 and 512 of cowpea mosaic virus M RNA is able to support internal initiation of translation in vitro.

Cowpea mosaic virus M RNA is translated in vitro as well as in vivo into two C-coterminal polyproteins of Mr 105K and 95K. Initiation of translation of the 95K protein gene occurs at an AUG codon at position 512 of M RNA, 351 nucleotides downstream of the initiation codon of the 105K protein gene at position 161. By employing an in vitro transcription and translation system it was determined that this 351 nucleotide sequence has the capacity to direct ribosomes to initiate translation at a downstream start codon. This effect is independent of the position of this sequence in an mRNA. Furthermore, evidence has been obtained that scanning ribosomes can bypass the AUG at position 161. Thus, both leaky scanning and internal entry are mechanisms for the initiation of translation of the 95K protein gene.

The complete sequence of soybean chlorotic mottle virus DNA and the identification of a novel promoter.

The complete nucleotide sequence of an infectious clone of soybean chlorotic mottle virus (SoyCMV) DNA was determined and compared with those of three other caulimoviruses, cauliflower mosaic virus (CaMV), carnation etched ring virus and figwort mosaic virus. The double-stranded DNA genome of SoyCMV (8,175 bp) contained nine open reading frames (ORFs) and one large intergenic region. The primer binding sites, gene organization and size of ORFs were similar to those of the other caulimoviruses, except for ORF I, which was split into ORF Ia and Ib. The amino acid sequences deduced from each ORF showed only short, highly homologous regions in several of the corresponding ORFs of the three other caulimoviruses. A promoter fragment of 378 bp in SoyCMV ORF III showed a strong expression activity, comparable to that of the CaMV 35S promoter, in tobacco mesophyll protoplasts as determined by a beta-glucuronidase assay using electrotransfection. The fragment contained CAAT and TATA boxes but no transcriptional enhancer signal as reported for the CaMV 35S promoter. Instead, it had sequences homologous to a part of the translational enhancer signal reported for the 5'-leader sequence of tobacco mosaic virus RNA.

Improvements of the infectivity of in vitro transcripts from cloned cowpea mosaic virus cDNA: impact of terminal nucleotide sequences.

Full-length DNA copies of both B- and M-RNA of cowpea mosaic virus (CPMV) were constructed downstream from a T7 promoter. By removal of nucleotides from the promoter sequence, B- and M-RNA-like transcripts with varying numbers of additional nonviral sequences at the 5' end were obtained upon transcription with T7 RNA polymerase. The infectivity of the transcripts in cowpea protoplasts was greatly affected by only a few extra nonviral nucleotides at the 5' end. The addition of about 400 nonviral nucleotides at the 3' end did not have any effect. Using the most infectious transcripts, in 40% of the cowpea protoplasts replication and expression of B-RNA like transcripts were observed and in 10% of the protoplasts both B- and M-RNA-like transcripts multiplied. Moreover, cowpea plants could also be infected with these transcripts. Sequence analysis showed that the 5' terminus of the M-RNA transcripts and the 3' terminus of the B-RNA transcripts were completely restored during replication in plants, including a poly(A) tail of variable length. Swapping experiments have been used to identify an influential point mutation in the coding region for the viral polymerase of a noninfectious B transcript. This experiment demonstrates the potential of the optimized infection system for future analysis of virus-encoded functions.

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.

Infectious RNA transcripts derived from full-length DNA copies of the genomic RNAs of cowpea mosaic virus.

A set of full-length DNA copies of both M and B RNA of cowpea mosaic virus (CPMV) was cloned downstream of a phage T7 promoter. Upon in vitro transcription using T7 RNA polymerase, M and B RNA-like transcripts were obtained from these DNA copies with only two additional nucleotides at the 5' end and five extra nucleotides at the 3' end in comparison to natural viral RNA. In cowpea protoplasts the transcripts of several cDNA clones of B RNA were able to replicate leading to detectable synthesis of viral RNA and proteins. Transcripts of M cDNA clones inoculated together with these B RNA transcripts were also expressed, although the number of protoplasts in which both transcripts were expressed was very low. Preliminary infectivity tests with mutagenized RNA transcripts indicate essential roles of the B RNA-encoded 24K and 32K polypeptides in viral RNA replication.

Two viral proteins involved in the proteolytic processing of the cowpea mosaic virus polyproteins.

A series of specific deletion mutants derived from a full-length cDNA clone of cowpea mosaic virus (CPMV) B RNA was constructed with the aim to study the role of viral proteins in the proteolytic processing of the primary translation products. For the same purpose cDNA clones were constructed having sequences derived from both M and B RNA of CPMV. In vitro transcripts prepared from these clones with T7 RNA polymerase, were efficiently translated in rabbit reticulocyte lysates. The translation products obtained were processed in the lysate by specific proteolytic cleavages into smaller products, which made it possible to study subsequently the effect of the various mutations on this process. The results obtained indicate that the B RNA-encoded 24K polypeptide represents a protease responsible for all cleavages in the polyproteins produced by both CPMV B and M RNA. For efficient cleavage of the glutamine-methionine site in the M RNA encoded polyprotein the presence of a second B RNA encoded protein, the 32K polypeptide, is essential, although the 32K polypeptide itself does not have proteolytic activity. A number of cleavage-site mutants were constructed in which the coding sequence for the glutamine-glycine cleavage site between the two capsid proteins was changed. Subsequent in vitro transcription and translation of these cleavage site mutants show that a correct dipeptide sequence is a prerequisite for efficient cleavage but that the folding of the polypeptide chain also plays an important role in the formation of a cleavage site.