Characterization of the P1 protein and coding region of the zucchini yellow mosaic virus

Genome characterization of zucchini yellow mosaic virus infecting cucurbits reveals the presence of a new genotype in Trinidad and Tobago in the Caribbean region

Zucchini yellow mosaic virus (ZYMV) is a member of the genus Potyvirus that is becoming a serious pathogen of pumpkin and other cucurbits in Trinidad and Tobago and the entire Caribbean region. In this study, four ZYMV isolates infecting pumpkin in Trinidad and Tobago were characterized by complete genome sequencing. Phylogenetic analysis showed 5.9-6.0% nt and 7.7-7.9% aa sequence divergence in comparison to the most closely related isolates NAT and AG from Israel and SE04T from Slovakia. Based on the variations in the complete genome sequence as well as individual gene sequences, a new genotype, designated ZYMV-Trini, is proposed for these isolates. Among the gene sequences of ZYMV-Trini isolates, the greatest variation was observed in the HC-Pro gene, with 20.8% aa sequence divergence from their closest relatives, whereas the least variation was observed in the NIb, P3, and CP genes, with 1.8-2.2% aa sequence divergence. This study also showed that transmission of ZYMV can occur through seeds, but this was less common than transmission via the aphid Aphis gossypii. The progression of ZYMV in pumpkin seedlings was quantified by RT-qPCR, which showed a rapid surge in viral load after 37 days. From recombination analysis, it could be concluded that the isolates SE04T from Slovakia, NAT from Israel, and AG from Israel have made major contributions to the genome architecture of ZYMV-Trini isolates.

P1 peptidase--a mysterious protein of family Potyviridae

The Potyviridae family, named after its type member, Potato virus Y (PVY), is the largest of the 65 plant virus groups and families currently recognized. The coding region for P1 peptidase is located at the very beginning of the viral genome of the family Potyviridae. Until recently P1 was thought of as serine peptidase with RNA-binding activity and with possible influence in cell-to-cell viral spreading. This N-terminal protein, among all of the potyviruses, is the most divergent protein: varying in length and in its amino acid sequence. Nevertheless, P1 peptidase in many ways is still a mysterious viral protein. In this review, we would like to offer a comprehensive overview, discussing the proteomic, biochemical and phylogenetic views of the P1 protein.

Zucchini yellow mosaic virus: insect transmission and pathogenicity -the tails of two proteins

SUMMARY Taxonomy: Zucchini yellow mosaic virus (ZYMV) is a member of genus Potyvirus, family Potyviridae. ZYMV is a positive-strand RNA virus. Physical properties: Virions are flexuous filaments of 680-730 nm in length and 11-13 nm in diameter, composed of about 2000 subunits of a single 31-kDa protein (calculated). The genome RNA size is 9.6 kb covalently linked to a viral-encoded protein (the VPg) at the 5' end, and with a 3' poly A tail. The 5' end of the sequence is AU-rich (69%). Viral proteins: The genome is expressed as a polyprotein cleaved by three viral proteases and processed into ten putative mature proteins. The structural coat protein is processed from the carboxyl terminus of the polyprotein and is highly immunogenic. Host and symptoms: Natural and experimental infection has been reported mainly in the Cucurbitaceae. Experimental local lesion hosts include Chenopodium amaranticolour, C. quinoa and Gomphrena globosa. Some ZYMV strains cause symptomless infection as in Ranunculus sardous, Nicotiana benthamiana and Sesamum indicum. ZYMV causes stunting and major foliar deformation with dark green blisters and mosaics in cucurbit hosts, eventually developing a filamentous leaf phenotype. In general, symptoms are severe on cucurbit hosts and cause dramatic reductions in yields due to severe fruit deformation. The virus is present in all the plant tissues at relatively high concentrations (c. 0.1 mg/mL of purified virus per 1 g fresh leaf tissue). The most suitable species for maintenance and purification is Cucurbita pepo.

TRANSMISSION

ZYMV is efficiently transmitted by aphids in a non-persistent manner. The coat protein (CP) and the helper component-protease (HC-Pro) are required for aphid transmission, through the CP DAG motif and the HC-Pro KLSC and PTK motifs. Mechanical transmission is efficient both in the laboratory and naturally. Economic importance: ZYMV disease is a major constraint in the production of cucurbits world-wide. The virus can cause massive damage (to total loss) to cucurbit crops, and prevents the growth of some cucurbit crops in certain areas. Control of ZYMV requires the integration of conventional resistance and transgenic breeding along with cross-protection technologies.

A novel insertion site inside the potyvirus P1 cistron allows expression of heterologous proteins and suggests some P1 functions

The P1 cistron encodes the first and most variable part of the polyprotein of potyviruses. A site tolerant to a pentapeptide insertion at the N-terminus of Potato virus A P1 (Genome Res. 12, 584-594) was used to express heterologous proteins (insertions up to 783 nucleotides) with or without flanking new proteolytic sites. Aequorea victoria green fluorescent protein (GFP) accumulated to high levels when proteolytically released from P1 and showed strong fluorescence in leaves systemically infected with vector virus. Deletions in GFP and adjacent viral sequences emerged 2-4 weeks after infection, revealing putative recombination hot spots. The inserts in P1 diminished infectivity host-specifically, reduced virus accumulation in protoplasts and systemically infected leaves, alleviated symptoms and reduced accumulation of mRNA and HCpro in cis in a virus-free system. This heterologous protein expression site is the first within a protein-encoding cistron and the third in the genome of potyviruses.

Serological Studies Using Polyclonal Antisera Prepared Against the Viral Coat Protein of Four Begomoviruses Expressed in Escherichia coli

Polyclonal rabbit antisera were produced to the coat protein of Bean golden mosaic virus Brazil isolate (BGMV), Cabbage leaf curl virus (CabLCV), Tomato yellow leaf curl virus (TYLCV), and Tomato mottle virus (ToMoV), all expressed in Escherichia coli by the pETh expression vector. The expressed coat protein of each virus was purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis for use as an immunogen. The antisera to BGMV, CabLCV, TYLCV, and ToMoV reacted in indirect (plate-trapping) enzyme-linked immunosorbent assay (ELISA) with extracts from begomovirus-infected tissue. The antisera to BGMV, CabLCV, TYLCV, and ToMoV also reacted specifically with the test begomovirus antigens in leaf imprint blots and Western blots. The CabLCV and TYLCV antisera were used to detect Bean golden yellow mosaic virus antigens by immunogold labeling of thin sections of infected bean tissues. In tissue blot immunoassays, the TYLCV antiserum reacted well with TYLCV antigens but not with ToMoV antigens, while CabLCV antiserum reacted well with ToMoV antigens and weakly with TYLCV antigens. The results indicate that polyclonal antisera prepared to expressed begomovirus coat proteins were useful for the detection of begomoviruses in an array of assays.

Analysis of the P1 gene sequences and the 3'-terminal sequences and secondary structures of the single-stranded RNA genome of Potato virus V

The immunocapture reverse transcriptase PCR method (IC-RT-PCR) was used to selectively amplify specific genome sequences of an isolate of Potato virus V (PVV, genus Potyvirus) from a potato plant infected by multiple viruses in the field in Finland. The sequences of the 5'- and 3'-non-translated regions (NTR) and the P1-and coat protein (CP)-encoding sequences were determined because they are the most variable genomic regions in potyviruses. The sequences of the new Finnish PVV isolate obtained in this study were compared to the sequences of eight PVV isolates characterized from other European countries. The results indicated little genetic variability among the European PVV isolates (nt identity values > 96% for all regions examined). Most PVV isolates were grouped according to their geographical origin using P1-sequences for a phylogenetic analysis. The nucleotide substitution patterns for P1 and the CP genes revealed that variability is due to a random genetic drift. Comparison of the secondary structure predictions for the unusually long 3'-non-translated region (3'-NTR) of PVV to the 3'-NTR of Tobacco etch virus (TEV) and other potyviruses revealed that some of the structures defining regions crucial for viral genome replication in TEV are present in PVV and other potyviruses.

Isolation and Molecular Characterization of a Chilean Isolate of Zucchini yellow mosaic virus

Zucchini yellow mosaic virus (ZYMV) was described in 1981 affecting squash, melon, and other cultivated cucurbits with severe stunting and yellowing symptoms. It was reported to be present in most countries where cucurbits are grown, and in Chile since 1995, from surveys using enzyme-linked immunosorbent assay (ELISA) but without further characterization. A potyvirus was isolated from ELISA-positive symptomatic plants. The results indicate that this virus is ZYMV based on symptoms on herbaceous indicators, immunospecific electron microscopy of the purified particle, and sequencing of 395 bases of the 3' end of the coat protein gene. The virus was detected in melon, watermelon, and squash plants. In agreement with previous descriptions for ZYMV, the Chilean isolate is a flexuous filamentous particle 740 nm long with one main protein of approximately 36 kDa. Nucleotide sequence comparisons of the 3' portion of the coat protein gene revealed a high similarity to the Connecticut and California strains.

A Point Mutation in the FRNK Motif of the Potyvirus Helper Component-Protease Gene Alters Symptom Expression in Cucurbits and Elicits Protection Against the Severe Homologous Virus

Sequence comparison had previously shown three amino acid changes in conserved motifs in the 455-amino acid sequence of the helper component-protease (HC-Pro) between a severe field strain of Zucchini yellow mosaic virus (ZYMV-NAT) and a mild field strain of ZYMV (ZYMV-WK). In this study, exchange of fragments and site-directed mutagenesis within the HC-Pro gene in an infectious clone of ZYMV enabled the effects of the mutations on symptom expression to be mapped. The substitution of Ile for Arg at position 180 in the conserved motif Phe-Arg-Asn-Lys (FRNK) of potyviruses was found to affect symptom expression. Infection of cucurbits with the engineered ZYMV (ZYMV-AG) that contained this mutation caused a dramatic symptom change from severe to mild in squash and to a symptom-free appearance in cucumber, melon, and watermelon. The Ile to Arg mutation was found to be stable, and no revertant virus was found after several passages through plants after long incubation periods. The AG strain was detected 4 days postinoculation and accumulated in cucurbits to a level and with kinetics similar to that of the wild-type ZYMV-AT strain. Cucurbit plants infected with the AG strain were protected against infection by the severe strain.

Heteroduplex Mobility and Sequence Analyses for Assessment of Variability of Zucchini yellow mosaic virus

ABSTRACT A heteroduplex mobility assay (HMA) was used to analyze the variability among five isolates of Zucchini yellow mosaic virus (ZYMV; TW-TC1, TW-CY2, TW-TN3, TW-TNML1, and TW-NT1) collected from cucurbit fields in different areas of Taiwan. A cDNA fragment of 760 bp covering the variable region of the N terminal half of the coat protein (CP) gene was amplified by reverse transcription-polymerase chain reaction (RT-PCR) and subsequently subjected to HMA analysis for sequence variation. When TW-NT1 combined with any of the other Taiwan isolates, the heteroduplexes obtained migrated much more slowly than did the heteroduplexes obtained in combinations among the other four Taiwan isolates, indicating that TW-TC1, TW-CY2, TW-TN3, and TW-TNML1 share a high degree of sequence homology, while the TW-NT1 isolate is more distinct. The complete nucleotide sequences of the CP genes and the 3' noncoding regions of the five isolates were determined from RT-PCR-derived cDNA clones. A phylogenetic tree derived from the actual sequences of the 760-bp fragments of the five Taiwan and another six ZYMV isolates from different geographic areas revealed four genotypes. TW-TNML1, TW-TC1, TWC-Y2, and TW-TN3 were in genotype I, while TW-NT1 and U.S. isolates were in genotype II. The Singapore and Reunion Island isolates were separated into genotypes III and IV, respectively. Comparison of the CP genes of the five Taiwan isolates indicated that they share 92.8 to 98.7% nucleotide identities and 96.4 to 99.3% amino acid identities. The amino acid positions 73, 102, 109, and 149 of the CP gene, where lysine, serine, arginine, and aspartic acid reside, respectively, were uniquely conserved for genotype I Taiwan isolates. Thus, results of HMA agreed well with those of phylogenetic analysis based on the sequence data of the five Taiwan ZYMV isolates. These five ZYMV isolates of known sequence can be used as reference strains for HMA to analyze the variability of ZYMV in Taiwan.

Variability of P1 protein of zucchini yellow mosaic virus for strain differentiation and phylogenetic analysis with other potyviruses

The complete nucleotide sequence of a Singapore isolate of zucchini yellow mosaic potyvirus (ZYMV-S) was determined from viral cDNA clones. The complete genome is 9603 nucleotides in length excluding the poly (A) tail. Computer analysis of the sequence revealed a single large open reading frame (ORF) that presumably encodes a polyprotein of 3082 amino acids with a calculated molecular weight of 350 kDa. Analysis of the helper component (HC) protein showed that the highly conserved motif K-I-T-C which is involved in aphid transmission appeared as K-L-S-C. There is also a change of D-A-G to G-A-G triplet near the N-terminal of the coat protein (CP). Amino acid sequence identity comparison of ZYMV-S gene products with the California and Reunion Island isolates of ZYMV revealed a minimum range of 65-75% to a maximum range of 95-98%. Comparison with other distinct potyviruses showed a low degree of identity from 19-74%. The 5' untranslated region (UTR) of ZYMV-S showed 67% and 72% identity when compared with the California and Reunion Island isolates, respectively. The sequence variability in the 5' UTR of ZYMV can be exploited for strain differentiation and phylogenetic analysis. ZYMV-S shared 94% and 82% identity in the 3' UTR as compared to the California and Reunion Island isolates, respectively. The P1 protein of ZYMV-S shared moderate sequence variability among ZYMV isolates but high sequence variability among all potyviruses. In addition, phylogenetic analysis using the P1 protein indicated that highly variable proteins in the viral genome could also be employed in the study of potyvirus taxonomy and used for strain differentiation.

Specificity of TAS-ELISA for Beet Necrotic Yellow Vein Virus and Its Application for Determining Rhizomania Resistance in Field-Grown Sugar Beets

Levels of beet necrotic yellow vein virus (BNYVV), as measured by triple-antibody sandwich-enzyme-linked immunosorbent assay (TAS-ELISA), were compared with biological evaluations in representative commercial and experimental sugar beet cultivars developed for production in the United States and ranging in their reactions to rhizomania from uniformly susceptible to highly resistant. TAS-ELISA was specific for BNYVV and did not react with related soilborne sugar beet viruses. Differences in absorbance (A_405nm) values measured in eight cultivars closely correlated with the dosage and frequency of the Rz allele, which conditions resistance to BNYVV. A diploid (Rzrz) hybrid had a significantly lower absorbance value (less virus) than a similar triploid (Rzrzrz) hybrid. Cultivars that segregated (Rzrz:rzrz) had higher absorbance values than uniformly resistant (Rzrz) hybrids, as was expected. For all cultivars, absorbance values decreased as the season progressed. Absorbance value was significantly positively correlated with rhizomania disease index score and negatively correlated with individual root weight, plot root weight, and sugar yield. This information should be useful in resistance-breeding and -evaluation programs and in the sugar industry when considering cultivar choice, inoculum production, and future crop rotations.

Phylogenetic relationships within the family potyviridae: wheat streak mosaic virus and brome streak mosaic virus are not members of the genus rymovirus

ABSTRACT The complete nucleotide sequence of wheat streak mosaic virus (WSMV) has been determined based on complementary DNA clones derived from the 9,384-nucleotide (nt) RNA of the virus. The genome of WSMV has a 130-nt 5' leader and 149-nt 3'-untranslated region and is polyadenylated at the 3' end. WSMV RNA encodes a single polyprotein of 3,035 amino acid residues and has a deduced genome organization typical for a member of the family Potyviridae (5'-P1/HC-Pro/P3/6K1/CI/6K2/VPg-NIa/NIb/CP-3'). Because WSMV shares with ryegrass mosaic virus (RGMV) the biological property of transmission by eriophyid mites, WSMV has been assigned to the genus Rymovirus, of which RGMV is the type species. Phylogenetic analyses were conducted with complete polyprotein or NIb protein sequences of 11 members of the family Potyviridae, including viruses of monocots or dicots and viruses transmitted by aphids, whiteflies, and mites. WSMV and the monocot-infecting, mite-transmitted brome streak mosaic virus (BrSMV) are sister taxa and share a most recent common ancestor with the whitefly-transmitted sweet potato mild mottle virus, the type species of the proposed genus "Ipomovirus." In contrast, RGMV shares a most recent common ancestor with aphid-transmitted species of the genus Potyvirus. These results indicate that WSMV and BrSMV should be classified within a new genus of the family Potyviridae and should not be considered species of the genus Rymovirus.

A cDNA clone to clover yellow vein potyvirus genome is highly infectious

We obtained a highly infectious cDNA clone of clover yellow vein virus (CIYVV). The cDNA fragments, from which a full-length cDNA clone was constructed, were sequenced, and the complete nucleotide sequence of C1YVV RNA was determined. The viral genome is 9584 nucleotides (nt) in length excluding the poly(A) tail and contains one open reading frame (ORF) encoding a large polyprotein of 3072 amino acids. The non-coding region preceding the ORF is 190 nt long. The termination codon is followed by a 175-nt sequence. Seven potential protease NIa, one HC-pro and one P1 protease recognition sites were found in the C1YVV polyprotein by searching for cleavage consensus sequences among the potyvirus group. The cleavage dipeptides of C1YVV NIa protease are Q(E)/S(A,G). The F is conserved at the -2 position from the cleavage site except for at the P3/6K1 junction, and the V conserved at the -4 position among many potyviruses is not present at all. The genome organization of C1YVV was determined, and the amino acid sequence was compared with that of other potyviruses. The full-length cDNA clone of C1YVV was constructed by combining cDNA fragments and placed it under the control of the cauliflower mosaic virus 35S promoter. The full-length cDNA was constructed so that no extra nucleotide was present at the transcription initiation site and only 10 adenine residues were present at the 3' end of the C1YVV cDNA clone. Mechanical inoculation of a circular-formed plasmid DNA onto broad bean seedlings led to systemic infection, and the symptoms were similar to those caused by the wild-type virus but rather mild. Plasmid diluted as low as 500 pg/microl was able to induce symptoms, demonstrating that this full-length C1YVV cDNA is more infectious than any other infectious cDNAs so far reported. Filamentous particles reacting with the antiserum to C1YVV were observed in the crude sap of infected plants by immunoelectron microscopy, and genome replication was demonstrated by RT-PCR of 3' non-coding regions of C1YVV genome in total plant RNAs.

Induction of antibodies to plant viral proteins by DNA-based immunization

DNA-based immunization is a promising new technique for generating antibodies in laboratory animals for diagnostic purposes in biological science. The main advantages are the elimination of time and labor and the technically demanding steps of antigen purification. The DNA sequence of the protein of interest, cloned in a suitable in vivo expression vector that is administered intramuscularly or intradermally, is sufficient to induce an immune response in animals. We report the induction of antibodies to tobacco mosaic virus (TMV) coat protein (CP) as a highly immunogenic structural protein and potato virus Y (PVY) P1 protein (P1) as a nonstructural protein. The appropriate nucleotide sequences were introduced in a mammalian expression vector (pSG5) and injected intramuscularly into New Zealand White rabbits (Oryctolagus cuniculus). By 10 days post-injection (dpi) a specific immune response was detected against TMV-CP, while it took about 5 weeks for a response to PVY P1. In both cases the antibody titers were significantly above the corresponding pre-immune serum, however, they were considerably below the titer of the matching conventionally produced antiserum. To our knowledge, this is the first report of DNA-based immunization in order to generate antibodies to plant viral proteins, but further improvements are necessary to increase antibody titers before this promising new technique can be introduced broadly in plant science for diagnostic purposes.

Sequence and phylogenetic analysis of the cytoplasmic inclusion protein gene of zucchini yellow mosaic potyvirus: its role in classification of the Potyviridae

The cytoplasmic inclusion (CI) gene of a Singapore isolate of zucchini yellow mosaic virus (ZYMV-S) was sequenced and compared with CI of 14 other potyviruses. In addition to the consensus sequence GAVGSGKST of nucleotide binding motif (NTBM) which is implicated as a membrane-binding component of the RNA helicase complex, five other conserved motifs were found. Phylogenetic trees were constructed from sequence data for the CI and the coat protein. Similar branching patterns obtained from both CI and coat protein analyses suggests that phylogenetic relationship among potyviruses can be determined using the CI. We propose that phylogenetic analysis of CI gene may be used as an alternative approach for the study of evolution within the family Potyviridae.