Genetic Variability and Evidence of a New Subgroup in Watermelon Mosaic Virus Isolates

Watermelon mosaic virus (WMV) is one of the important Potyviruses that infect cucurbits worldwide. To better understand the population structure of WMV in the United States (U.S.), 57 isolates were collected from cucurbit fields located in nine southern states. The complete coat protein gene of all WMV isolates was cloned, sequenced and compared with 89 reported WMV isolates. The nucleotide and amino acid sequence identities among the U.S. WMV isolates ranged from 88.9 to 99.7% and from 91.5 to 100%, respectively. Phylogenetic analysis revealed that all the U.S. WMV isolates irrespective of their geographic origin or hosts belonged to Group 3. However, the fifty-seven isolates made three clusters in G3, where two clusters were similar to previously reported subgroups EM1 and EM2, and the third cluster, containing nine WMV isolates, formed a distinct subgroup named EM5 in this study. The ratio of non-synonymous to synonymous nucleotide substitution was low indicating the occurrence of negative purifying selection in the CP gene of WMV. Phylogenetic analysis of selected 37 complete genome sequences of WMV isolates also supported the above major grouping. Recombination analysis in the CP genes confirmed various recombinant events, indicating that purifying selection and recombination are the two dominant forces for the evolution of WMV isolates in the U.S.

First report of watermelon crinkle leaf-associated virus 1 (WCLaV-1) and WCLaV-2 in watermelon (Citrullus lanatus L.) plants co-infected with Cucurbit chlorotic yellows virus in Florida

Watermelon (Citrullus lanatus L.) and other cucurbits are major crops in Florida. During the 2020 and 2021 seasons, watermelon plants with foliar virus-like symptoms of yellow mottling and chlorosis, mild leaf wrinkling and thickened leaves were observed in commercial fields (40 to 150 ha) in five counties (Desoto, Glades, Osceola, Seminole, and Charlotte) at >50% field incidence. Initial screening of 13 field-collected samples (2 to 4/County) for potyviruses with the Agdia POTY Immunostrip (Agdia, Inc. Elkhart, IN) were negative. Total nucleic acid extracts from each sample (RNeasy Plant Mini Kit, Qiagen, Germantown, MD) were used in one-step RT-PCR (Qiagen OneStep RT-PCR kit) with species-specific primer targeting squash vein yellowing virus (SqVYV), papaya ringspot virus-W (PRSV-W) (Adkins et al., 2008), cucurbit yellow stunting disorder virus (CYSDV) (Polston et al. 2008), cucurbit chlorotic yellows virus (CCYV) (Hernandez et al., 2021a), watermelon crinkle leaf-associated virus 1 (WCLaV-1), and WCLaV-2 (Hernandez et al., 2021b). The samples were also tested for cucurbit leaf crumple virus (CuLCrV) as per Hagen et al. (2008). All 13 samples were negative for SqVYV, PRSV-W, CuLCrV, and CYSDV, but 7 samples (53.8%) from 4 counties tested positive for CCYV, 12 (92.3%) from 5 counties were positive for WCLaV-1, and WCLaV-2 was detected in 8 samples (61.5%) from 5 counties. Three samples were singly infected with WCLaV-1 while the remaining 10 were mixed infected with different combination of 2 or 3 viruses. Notably, symptoms on all 13 plants were visually indistinguishable. To verify the results, two randomly chosen gene-specific fragments per virus, obtained with primers CCYV-v1330/c2369, CCYV-v4881/c5736, WCLaV-1vRP/1cRP, WCLaV-1vMP/1cMP, WCLaV-2vRP/2cRP, and WLaV 2vMP/2cMP, were excised from the gel, cloned, and Sanger-sequenced as described (Hernandez et al., 2021a, 2021b). In pairwise comparisons, the ~1 kb partial ORF1a (GenBank accession nos. MZ325846 to MZ325847) and 753 bp complete coat protein cistron (MZ325848 to MZ325849) of CCYV from Florida shared 98.9-99.5%/98.4-99.6% nucleotide (nt)/amino acid (aa) and 99.4-99.8%/99.6-100% nt/aa identities, respectively with the corresponding sequences of global CCYV isolates. The partial RNA1 (MZ325850 to MZ325851) and RNA2 (MZ325852 to MZ325853) sequences of WCLaV-1 from Florida shared 99.2-99.8%/100% nt/aa and 98.9-100%/99.3-100% nt/aa identities, respectively with the corresponding global sequences of WCLaV-1 isolates. Lastly, the partial RNA1 (MZ325854 to MZ325857) and RNA2 (MZ325858 to MZ325861) sequences of WCLaV-2 from Florida shared 96.4-99.8%/97-100% nt/aa and 96.5-100%/95.9-100% nt/aa identities, respectively with the corresponding global sequences of WCLaV-2 isolates. This is the first report of WCLaV-1 and WCLaV-2 from Florida and the first documentation of the occurrence of CCYV in South Florida. CCYV has been reported previously from California (Wintermantel et al. 2019), Georgia (Kavalappara et al. 2021), and recently from North Florida (M. Paret, pers. comm) but WCLaV-1 and WCLaV-2 have only been reported from Texas (Hernandez et al., 2021b), after their discovery in China (Xin et al. 2017). The results indicate further expansion of the geographical range of these cucurbit-infecting viruses, although their longer but undetected presence in Florida is plausible due to the resemblance of their associated symptoms with those attributed to known viruses. References Adkins, et al., 2008. Plant Dis. 92:1119-1123. https://apsjournals.apsnet.org/doi/10.1094/PDIS-92-7-1119. Hagen, et al. 2008. Plant Dis. 92:781-793. https://apsjournals.apsnet.org/doi/pdfplus/10.1094/PDIS-92-5-0781. Hernandez, et al. 2021a. Plant Dis. https://doi.org/10.1094/PDIS-02-21-0378-PDN. Hernandez, et al., 2021b. Plant Dis. https://doi.org/10.1094/PDIS-02-21-0249-PDN Kavalappara, et al., 2021. Plant Dis. https://doi.org/10.1094/PDIS-11-20-2429-PDN. Polston, et al. 2008. Plant Dis. 92(8):1251. https://apsjournals.apsnet.org/doi/10.1094/PDIS-92-8-1251B. Wintermantel, et al., 2019. Plant Dis. 103(4):778. https://doi.org/10.1094/PDIS-08-18-1390-PDN. Xin, et al., 2017. Front. Microbiol. 8:1514, doi: 10.3389/fmicb.2017.01514.

The Symptom and Genetic Diversity of Cassava Brown Streak Viruses Infecting Cassava in East Africa

The genetic and symptom diversity of six virus isolates causing cassava brown streak disease (CBSD) in the endemic (Kenya, Mozambique, and Tanzania) and the recently affected epidemic areas (Uganda) of eastern Africa was studied. Five cassava varieties; Albert, Colombian, Ebwanateraka, TMS60444 (all susceptible) and Kiroba (tolerant) were graft inoculated with each isolate. Based on a number of parameters including the severity of leaf and root symptoms, and the extent of virus transmission by grafting, the viruses were classified as either severe or relatively mild. These results were further confirmed by the mechanical inoculation of 13 herbaceous hosts in which the virulent isolates caused plant death inNicotiana clevelandiiandN. benthamianawhereas the milder isolates did not. Phylogenetic analysis of complete coat protein gene sequences of these isolates together with sequences obtained from 14 other field-collected samples from Kenya and Zanzibar, and reference sequences grouped them into two distinct clusters, representing the two species of cassava brown streak viruses. Put together, these results did not suggest the association of a hypervirulent form of the virus with the current CBSD epidemic in Uganda. Identification of the severe and milder isolates, however, has further implications for disease management and quarantine requirements.

First Report of Cucumber mosaic virus in Anemone sp. in the United States

In the spring of 2008, more than a dozen, aphid-infested, anemone plants (Anemone sp.) grown at the campus of the University of Arkansas in Fayetteville showed stunting and mosaic, whereas only two were asymptomatic. Leaf homogenates from four symptomatic plants were inoculated onto Nicotiana benthamiana that became stunted and developed severe mosaic approximately 7 days postinoculation, whereas buffer-inoculated plants remained asymptomatic. Double-stranded RNA (dsRNA) extraction (4) from symptomatic anemone revealed the presence of four predominant bands of approximately 3.2, 2.9, 2.2, and 0.9 kbp, a pattern indicative of cucumovirus infection. Cucumber mosaic virus (CMV) is the only cucumovirus reported in anemone in Europe (2) and Israel (3), and for this reason, anemone and N. benthamiana plants were tested by Protein A ELISA with antisera against CMV developed by H. A. Scott. ELISA verified the presence of CMV in symptomatic anemone and inoculated N. benthamiana, while asymptomatic plants were free of the virus. Using cucumovirus degenerate primers, essentially as described by Choi et al. (1), a region of approximately 940 bases that includes the complete coat protein gene of the virus was amplified from symptomatic anemone and N. benthamiana but not asymptomatic plants of either species. This anemone isolate (GenBank Accession No. FJ375723) belongs to the IA subgroup of CMV because it shares 99% nucleotide and 100% amino acid sequence identities with the Fny isolates of the virus. To my knowledge, this is the first report of CMV infecting anemone in the United States and an important discovery for the ornamental industry since anemone is commonly grown together with several ornamental hosts of CMV in nursery and garden settings. References: (1) S. K. Choi et al. J. Virol. Methods 83:67, 1999. (2) M. Hollings. Ann. Appl. Biol. 45:44, 1957 (3) G. Loebenstein. Acta Hortic. 722:31, 2006 (4) I. E. Tzanetakis and R. R. Martin, J. Virol. Methods 149:167, 2008.

Variability of the coat protein gene of Grapevine leafroll-associated virus 3 in Brazil

Leafroll is an economically important disease affecting grapevines (Vitis spp.). Nine serologically distinct viruses, Grapevine leafroll-associated virus-1 through 9, are associated with this disease. The present study describes the coat protein gene sequence of four GLRaV-3 isolates occurring in the São Francisco River basin, Northeastern Brazil. The viral RNA was extracted from GLRaV-3 ELISA-positive plants and the complete coat protein gene was amplified by RT-PCR. Sequences were generated automatically and compared to the complete coat protein sequence from North American (NY1) and Chinese (Dawanhong Nº2 and SL10) GLRaV-3 isolates. The four studied isolates, named Pet-1 through 4, showed deduced amino acid identities of 98-100% (Pet-1 through 3) and 95% (Pet-4) with North American and Chinese isolates. A total of seventeen amino acid substitutions was detected among the four characterized isolates in comparison to the NY1, Dawanhong No.2 and SL10 sequences. The results indicated the existence of natural variation among GLRaV-3 isolates from grapevines, also demonstrating a lack of correlation between sequence data and geographic origin. This variability should be considered when selecting regions of the viral genome targeted for reliable and consistent virus molecular detection.

Nucleotide sequence of the coat protein gene of Lettuce big-vein virus

A sequence of 1425 nt was established that included the complete coat protein (CP) gene of Lettuce big-vein virus (LBVV). The LBVV CP gene encodes a 397 amino acid protein with a predicted M r of 44486. Antisera raised against synthetic peptides corresponding to N-terminal or C-terminal parts of the LBVV CP reacted in Western blot analysis with a protein with an M r of about 48000. RNA extracted from purified particles of LBVV by using proteinase K, SDS and phenol migrated in gels as two single-stranded RNA species of approximately 7·3 kb (ss-1) and 6·6 kb (ss-2). After denaturation by heat and annealing at room temperature, the RNA migrated as four species, ss-1, ss-2 and two additional double-stranded RNAs (ds-1 and ds-2). The Northern blot hybridization analysis using riboprobes from a full-length clone of the LBVV CP gene indicated that ss-2 has a negative-sense nature and contains the LBVV CP gene. Moreover, ds-2 is a double-stranded form of ss-2. Database searches showed that the LBVV CP most resembled the nucleocapsid proteins of rhabdoviruses. These results indicate that it would be appropriate to classify LBVV as a negative-sense single-stranded RNA virus rather than as a double-stranded RNA virus.

Differentiation of Biologically Distinct Peanut Stripe Potyvirus Strains by a Nucleotide Polymorphism-Based Assay

A necrotic strain of peanut stripe potyvirus (PStV-Ts) was used to design and test strain-differentiating oligonucleotides. The 3′ region of PStV-Ts, including a part of the NIb region, the complete coat protein (CP) gene, and the 3′-untranslated region, was cloned and sequenced. PStV-Ts had a high degree of sequence identity (92 to 95%) to the known non-necrotic (blotch) strains both at the nucleotide and amino acid sequence levels. Nucleotide sequence differences unique to the necrotic strain were identified when compared to the available non-necrotic isolates of PStV. Nucleotide polymorphism in the CP gene sequences was utilized in designing oligonucleotides that were specific to the necrotic strain, and were employed in an assay to differentiate the necrotic strain from non-necrotic. The 3′ end mismatch in the oligonucleotides contributed in particular to the differentiation of the strains. This approach facilitated rapid, sensitive, and reliable detection and differentiation of PStV strains.