Characterization of a New, Country Bean (Lablab purpureus) Lineage of Bean Common Mosaic Necrosis Virus.

Country bean (Lablab purpureus, family Fabaceae) is grown in subsistence agriculture in Bangladesh as a multipurpose crop for food, animal feed, and green manure. This study was undertaken to investigate the genetic diversity of bean common mosaic necrosis virus (BCMNV, genus Potyvirus, family Potyviridae) in country beans. Leaf samples from country beans showing yellowing, vein banding, and mosaic symptoms were collected during field surveys between 2015 and 2019 cropping seasons from farmers' fields in different geographic regions. These samples were tested by serological and molecular diagnostic assays for the presence of BCMNV. Virus-positive samples were subjected to high-throughput Illumina sequencing to generate near-complete genomes of BCMNV isolates. In pairwise comparisons, the polyprotein sequences of BCMNV isolates from Bangladesh showed greater than 98% identities among themselves and shared less than 84% sequence identity at the nucleotide level with virus isolates reported from other countries. In the phylogenetic analysis, BCMNV isolates from Bangladeshi country beans formed a separate clade from virus isolates reported from common beans in other countries in the Americas, Africa, Europe, and from East Timor. Grow-out studies showed seed-to-seedling transmission of BCMNV, implying a possible seedborne nature of the virus in country beans.

Grapevine Endophyte Endornavirus and Two New Endornaviruses Found Associated with Grapevines (Vitis vinifera L.) in Idaho, USA.

Five virus genomes, ranging between 12.0 and 12.3 kb in length and identified as endornaviruses, were discovered through a high-throughput sequencing (HTS) analysis of the total RNA samples extracted from two wine grape cultivars collected in the State of Idaho. One was found in a declining Chardonnay vine and was determined to be a local isolate of grapevine endophyte endornavirus (GEEV), and four others represented two novel endornaviruses named grapevine endornavirus 1 (GEV1) and grapevine endornavirus 2 (GEV2). All three virus genomes span a large, single open reading frame encoding polyproteins with easily identifiable helicase (HEL) and RNA-dependent RNA polymerase (RdRP) domains, while the GEV2 polyprotein also contains a glycosyltransferase domain. The GEV1 genome found in an asymptomatic Cabernet franc vine was related to, but distinct from, GEEV: the 5'-proximal, 4.7 kb segment of the GEV1 genome had a 72% identical nucleotide sequence to that of GEEV, while the rest of the genome displayed no significant similarity to the GEEV nucleotide sequence. Nevertheless, the amino acid sequence of the RdRP domain of GEV1 exhibited the closest affinity to the RdRP of GEEV. GEV2 was found in declining Chardonnay and asymptomatic Cabernet franc vines as three genetic variants exhibiting a 91.9-99.8% nucleotide sequence identity among each other; its RdRP had the closest affinity to the Shahe endorna-like virus 1 found in termites. In phylogenetic analyses, the RdRP and HEL domains of the GEV1 and GEV2 polyproteins were placed in two separate clades inside the large lineage of alphaendornaviruses, showing an affinity to GEEV and Phaseolus vulgaris endornavirus 1, respectively.

First report of tomato chlorotic dwarf viroid infecting litchi tomato (Solanum sisymbriifolium).

Litchi tomato (LT) (Solanum sisymbriifolium) is a solanaceous weed that is considered a biological control tool to manage potato cyst nematode (PCN) in Europe and is being explored for use in Idaho. Two Several LT lines were clonally maintained as stocks in the university greenhouse since 2013 and were also established in tissue culture at the same time. In 2018, tomato (Solanum lycopersicum cv. Alisa Craig) scions were grafted onto two LT rootstocks originating either from healthy-looking greenhouse stocks or from tissue culture-maintained plants. Unexpectedly, tomatoes grafted onto the greenhouse-maintained rootstocks of LT displayed severe symptoms of stunting, foliar deformation, and chlorosis, while grafts onto the same LT lines from tissue culture produced healthy-looking tomato plants. Tests for the presence of several viruses known to infect solanaceous plants were conducted on symptomatic tomato scion tissues using ImmunoStrips (Agdia, Elkhard, IN) and RT-PCR (Elwan et al. 2017) but yielded negative results. High throughput sequencing (HTS) was then used to identify possible pathogens that could have been responsible for the symptoms observed in tomato scions. Samples from two symptomatic tomato scions, two asymptomatic scions grafted onto the tissue culture-derived plants, and two greenhouse-maintained rootstocks were subjected to HTS. Total RNA from the four tomato and two LT samples was depleted of ribosomal RNA and subjected to HTS on an Illumina MiSeq platform producing 300-bp paired-end reads and raw reads were adapter and quality cleaned. For the tomato samples, the clean reads were mapped against the S. lycopersicum L. reference genome, and unmapped paired reads were assembled producing between 4,368 and 8,645 contigs. For the LT samples, all clean reads were directly assembled, producing 13,982 and 18,595 contigs. In the symptomatic tomato scions and the two LT rootstock samples, a 487-nt contig was found, comprising an ~1.35 tomato chlorotic dwarf viroid (TCDVd) genome and exhibiting 99.7% identity with it (GenBank accession AF162131; Singh et al. 1999). No other virus-related or viroid contigs were identified. RT-PCR analysis using a pospiviroid primer set Pospi1-FW/RE (Verhoeven et al. 2004), and a TCDVd-specific primer set TCDVd-Fw/TCDVd-Rev (Olmedo-Velarde et al. 2019) produced 198-nt and 218-nt bands, respectively, thus confirming the presence of TCDVd in tomato and LT samples. These PCR products were Sanger sequenced and confirmed to be TCDVd-specific; the complete sequence of the Idaho isolate of TCDVd was deposited in GenBank under the accession number OQ679776. Presence of TCDVd in LT plant tissue was confirmed by the APHIS PPQ Laboratory in Laurel, MD. Asymptomatic tomatoes and LT plants from tissue culture were found negative for TCDVd. Previously, TCDVd was reported to affect greenhouse tomatoes in Arizona and Hawaii (Ling et al. et al. 2009; Olmedo-Velarde et al. 2019), however, this is the first report of TCDVd infecting litchi tomato (S. sisymbriifolium). Five additional greenhouse-maintained LT lines were found TCDVd-positive using RT-PCR and Sanger sequencing. Given the very mild or asymptomatic infection of TCDVd in this host, molecular diagnostic methods should be used to screen LT lines for the presence of this viroid to avoid inadvertent spread of TCDVd. Another viroid, potato spindle tuber viroid, was reported to be transmitted through LT seed (Fowkes et al. 2021), and transmission of TCDVd through LT seed may also be responsible for this TCDVd outbreak in the university greenhouse, although no direct evidence was collected. To the best of our knowledge, this is the first report of TCDVd infection in S. sisymbriifolium and also the first report of the TCDVd occurrence in Idaho.

A Novel Rhabdovirus Associated with the Idaho Population of Potato Cyst Nematode Globodera pallida.

Globodera pallida, a potato cyst nematode (PCN), is a quarantine endoparasitic pest of potato (Solanum tuberosum) in the US due to its effects on yield and quality of potato tubers. A new rhabdovirus, named potato cyst nematode rhabdovirus (PcRV), was revealed and characterized in the G. pallida populations collected in Idaho through use of high-throughput sequencing (HTS) and RT-PCR and found to be most closely related to soybean cyst nematode rhabdovirus (ScRV). PcRV has a 13,604 bp long, single-stranded RNA genome encoding five open reading frames, including four rhabdovirus-specific genes, N, P, G, and L, and one unknown gene. PcRV was found present in eggs, invasive second-stage juveniles, and parasitic females of G. pallida, implying a vertical transmission mode. RT-PCR and partial sequencing of PcRV in laboratory-reared G. pallida populations maintained over five years suggested that the virus is highly persistent and genetically stable. Two other Globodera spp. reproducing on potato and reported in the US, G. rostochiensis and G. ellingtonae, tested negative for PcRV presence. To the best of our knowledge, PcRV is the first virus experimentally found infecting G. pallida. Based on their similar genome organizations, the phylogeny of their RNA-dependent RNA polymerase domains (L gene), and relatively high identity levels in their protein products, PcRV and ScRV are proposed to form a new genus, provisionally named "Gammanemrhavirus", within the family Rhabdoviridae.

A Novel Flavi-like Virus in Alfalfa (Medicago sativa L.) Crops along the Snake River Valley.

Alfalfa is an important perennial forage crop in Idaho supporting dairy and cattle industries that is typically grown in the same field for as many as 4 years. Alfalfa stands of different ages were subjected to screening for viruses using high-throughput sequencing and RT-PCR. The two most common viruses found were alfalfa mosaic virus and bean leafroll virus, along with Medicago sativa amalgavirus, two alphapartitiviruses, and one deltapartitivirus. Additionally, a new flavi-like virus with an unusual genome organization was discovered, dubbed Snake River alfalfa virus (SRAV). The 11,745 nt, positive-sense (+) RNA genome of SRAV encodes a single 3835 aa polyprotein with only two identifiable conserved domains, an RNA-dependent RNA polymerase (RdRP) and a predicted serine protease. Notably, unlike all +RNA virus genomes in the similar size range, the SRAV polyprotein contained no predicted helicase domain. In the RdRP phylogeny, SRAV was placed inside the flavi-like lineage as a sister clade to a branch consisting of hepaci-, and pegiviruses. To the best of our knowledge, SRAV is the first flavi-like virus identified in a plant host. Although commonly detected in alfalfa crops in southern Idaho, SRAV sequences were also amplified from thrips feeding in alfalfa stands in the area, suggesting a possible role of Frankliniella occidentalis in virus transmission.

A new picorna-like virus identified in populations of the potato psyllid Bactericera cockerelli.

The potato/tomato psyllid Bactericera cockerelli (Hemiptera: Triozidae) is a pest of Solanaceae plants and a vector of the pathogenic bacterium 'Candidatus Liberibacter solanacearum', which is associated with zebra chip disease in potato. This disease is controlled through insecticide treatments, and more environmentally friendly management options are desirable. The objective of this study was to identify viruses present in potato psyllid populations that might be used as biocontrol agents for this insect pest. A new picorna-like virus, tentatively named "Bactericera cockerelli picorna-like virus" (BcPLV), was discovered in B. cockerelli populations maintained in greenhouses, through the use of high-throughput sequencing data and subsequent confirmation by RT-PCR and Sanger sequencing. BcPLV has a positive-sense 9,939-nt RNA genome encoding a single 2,947-aa polyprotein and is related to the Diaphorina citri picorna-like virus (DcPLV) found in Asian citrus psyllid Diaphorina citri populations. Based on their genome organization and the phylogeny of their RNA-dependent RNA polymerase domains, BcPLV and DcPLV together are proposed to comprise a new genus, provisionally named "Psylloidivirus", within the family Iflaviridae.

Molecular and Biological Characterization of Recombinant Isolates of Potato virus Y Circulating in Potato Fields in Mexico.

Potato virus Y (PVY) is a significant threat to potato (Solanum tuberosum) production in Mexico. The presence of recombinant strains of PVY circulating in potato has been reported in the country, but no systematic study on the genetic diversity of PVY in potato and prevalence of PVY strains has been conducted yet. We report on a series of surveys in seed potato production areas in two states in Mexico, namely, Chihuahua and Jalisco, between 2011 and 2019. PVY was detected through the period of nine years in multiple potato cultivars in both states, often remaining asymptomatic in the most popular cultivars, such as 'Fianna' and 'Agata'. When typed to strain, all PVY samples studied were found to have N-serotype, and were all identified molecularly as isolates of the same recombinant strain, PVYNTN. Five of these PVY isolates were tested on tobacco (Nicotiana tabacum), where they induced vein necrosis supporting the molecular typing. This identification was also confirmed biologically on differential potato cultivars, where one PVYNTN isolate from the 2013 survey triggered the hypersensitive resistance conferred by the Nztbr gene in the cv. Maris Bard. Seven of these Mexican PVYNTN isolates, collected between 2013 and 2019, including two PVY isolates from potato tubers exhibiting potato tuber necrotic ringspot disease, were subjected to whole genome sequencing and found to show a typical PVYNTNa recombinant structure. When subjected to phylogenetic analysis, Mexican PVYNTN sequences clustered in more than three separate clades, suggesting multiple introductions of PVYNTN in the country. The wide circulation of the PVYNTN strain in Mexican potato should be considered by potato producers, to develop mitigation strategies for this PVY strain associated with tuber necrotic symptoms.

Genetic Diversity of Nine Non-Recombinant Potato virus Y Isolates From Three Biological Strain Groups: Historical and Geographical Insights.

Potato virus Y (PVY) isolates from potato currently exist as a complex of six biologically defined strain groups all containing nonrecombinant isolates and at least 14 recombinant minor phylogroups. Recent studies on eight historical UK potato PVY isolates preserved since 1984 found only nonrecombinants. Here, four of five PVY isolates from cultivated potato or wild Solanum spp. collected recently in Australia, Mexico, and the U.S.A. were typed by inoculation to tobacco plants and/or serological testing using monoclonal antibodies. Next, these five modern isolates and four additional historical UK isolates belonging to biological strain groups PVYC, PVYZ, or PVYN obtained from cultivated potato in 1943 to 1984 were sequenced. None of the nine complete PVY genomes obtained were recombinants. Phylogenetic analysis revealed that the four historical UK isolates were in minor phylogroups PVYC1 (YC-R), PVYO-O (YZ-CM1), PVYNA-N (YN-M), or PVYEu-N (YN-RM), Australian isolate YO-BL2 was in minor phylogroup PVYO-O5, and both Mexican isolate YN-Mex43 and U.S.A. isolates YN-MT12_Oth288, YN-MT12_Oth295, and YN-WWAA150131G42 were in minor phylogroup PVYEu-N. When combined, these new findings and those from the eight historical UK isolates sequenced earlier provide important historical insights concerning the diversity of early PVY populations in Europe and the appearance of recombinants in that part of the world. They and four recent Australian isolates sequenced earlier also provide geographical insights about the geographical distribution and diversity of PVY populations in Australia and North America.

Potato Virus Y (PVY) Isolates from Solanum betaceum Represent Three Novel Recombinants Within the PVYN Strain Group and Are Unable to Systemically Spread in Potato.

Tamarillo, or tree tomato (Solanum betaceum), is a perennial small tree or shrub species cultivated in subtropical areas for fresh fruit and juice production. In Ecuador, tamarillo orchards are affected by several viruses, with one previously identified as potato virus Y (PVY); however, the specific strain composition of PVY in tamarillo was not determined. In 2015 and 2016, eight tamarillo plants exhibiting symptoms of leaf drop, mosaic, and mottled fruit were sampled near Tumbaco and Quito, Ecuador. These tamarillo PVY isolates were able to systemically infect tobacco, Nicotiana benthamiana, naranjilla, and tamarillo. Seven of the eight PVY isolates from tamarillo exhibited N-serotype, while one of the PVY isolates studied, Tam15, had no identifiable serotype. One isolate, Tam17, had N-serotype but produced asymptomatic systemic infection in tobacco. In tamarillo, four tamarillo isolates induced mosaic and slight growth retardation and were unable to systemically infect pepper or potato. Tamarillo, on the other hand, was unable to support systemic infection of PVY isolates belonging to the PVYO and PVYEu-N strains. The whole genomes of eight PVY isolates were sequenced from a series of overlapping RT-PCR fragments. Phylogenetically, tamarillo PVY isolates were found to belong to the large PVYN lineage, in a new tamarillo clade. Recombination analysis revealed that these tamarillo PVY isolates represent at least three novel recombinant types not reported before. The combination of the biological and molecular properties found in these eight PVY isolates suggested the existence of a new tamarillo strain of PVY that may have coevolved with S. betaceum.

Characterization of a New Tymovirus Causing Stunting and Chlorotic Mosaic in Naranjilla (Solanum quitoense).

Naranjilla ("little orange"), also known as lulo (Solanum quitoense Lam.), is a perennial shrub species cultivated in the Andes for fresh fruit and juice production. In 2015, a naranjilla plant exhibiting stunting, mosaic, and chlorotic spots was sampled in the Pastaza province of Ecuador and maintained under greenhouse conditions. An infectious agent was mechanically transmitted to indicator plants and was subjected to biological and molecular characterization. Spherical particles approximately 30 nm in diameter, composed of a single 20-kDa capsid protein, were observed under an electron microscope in infected naranjilla plants. High-throughput sequencing conducted on inoculated Nicotiana benthamiana plants produced a single sequence contig sharing the closest relationship with several tymoviruses. The entire 6,245-nucleotide genome of a new tymovirus was amplified using reverse-transcription polymerase chain reaction and resequenced with the Sanger methodology. The genome had three open reading frames typical of tymoviruses, and displayed a whole-genome nucleotide identity level with the closest tymovirus, Eggplant mosaic virus, at 71% (90% coverage). This tymovirus from naranjilla was able to systemically infect eggplant, tamarillo, N. benthamiana, and naranjilla. In naranjilla, it produced mosaic, chlorotic spots, and stunting, similar to the symptoms observed in the original plant. The virus was unable to infect potato and tobacco and unable to systemically infect pepper plants, replicating only in inoculated leaves. We concluded that this virus represented a new tymovirus infecting naranjilla, and proposed the tentative name Naranjilla chlorotic mosaic virus (NarCMV).

Potato virus Y (PVY) Isolates from Physalis peruviana are Unable to Systemically Infect Potato or Pepper and Form a Distinct New Lineage Within the PVYC Strain Group.

Poha, or cape gooseberry (Physalis peruviana L.), is a plant species cultivated in Hawaii for fresh fruit production. In 2015, an outbreak of virus symptoms occurred on poha farms in the South Kohala District of the island of Hawaii. The plants displayed mosaic, stunting, and leaf deformation, and produced poor fruit. Initial testing found the problem associated with Potato virus Y (PVY) infection. Six individual PVY isolates, named Poha1 to Poha6, were collected from field-grown poha plants and subjected to biological and molecular characterization. All six isolates induced mosaic and vein clearing in tobacco, and three of them exhibited O-serotype while the other three reacted only with polyclonal antibodies and had no identifiable serotype. Until now, PVY isolates have been broadly divided into pepper or potato adapted; however, these six PVY isolates from poha were unable to establish systemic infection in pepper and in four tested potato cultivars. Whole-genome sequences for the six isolates were determined, and no evidence of recombination was found in any of them. Phylogenetic analysis placed poha PVY isolates in a distinct, monophyletic "Poha" clade within the PVYC lineage, suggesting that they represented a novel, biologically and evolutionarily unique group. The genetic diversity within this poha PVYC clade was unusually high, suggesting a long association of PVYC with this solanaceous host or a prolonged geographical separation of PVYC in poha in Hawaii.

Biological and molecular characterization of a tomato isolate of potato virus Y (PVY) of the PVYC lineage.

An isolate of potato virus Y (PVY), PVY-H14, was collected on the island of Oahu, Hawaii, from tomato plants exhibiting stunting and necrotic lesions on leaves. PVY-H14 triggered the hypersensitive resistance response in potato cultivars King Edward and Maris Bard, typical of a PVYC strain, and was unable to infect systemically the four tested cultivars, Desiree, Maris Bard, King Edward, and Russet Norkotah. Phylogenetic analysis of H14 and the whole genomes of 31 PVY isolates of non-recombinant strains of PVY placed PVY-H14 in the same clade with PVYC and several unclassified PVY isolates from tomato and tobacco.

A Recombinant of Bean common mosaic virus Induces Temperature-Insensitive Necrosis in an I Gene-Bearing Line of Common Bean.

The I gene is a single, dominant gene conferring temperature-sensitive resistance to all known strains of Bean common mosaic virus (BCMV) in common bean (Phaseolus vulgaris). However, the closely related Bean common mosaic necrosis virus (BCMNV) induces whole plant necrosis in I-bearing genotypes of common bean, and the presence of additional, recessive genes is required to prevent this severe whole plant necrotic reaction caused by BCMNV. Almost all known BCMNV isolates have so far been classified as having pathotype VI based on their interactions with the five BCMV resistance genes, and all have a distinct serotype A. Here, we describe a new isolate of BCMV, RU1M, capable of inducing whole plant necrosis in the presence of the I gene, that appears to belong to pathotype VII and exhibits B-serotype. Unlike other isolates of BCMV, RU1M was able to induce severe whole plant necrosis below 30°C in bean cultivar Jubila that carries the I gene and a protective recessive gene bc-1. The whole genome of RU1M was cloned and sequenced and determined to be 9,953 nucleotides long excluding poly(A), coding for a single polyprotein of 3,186 amino acids. Most of the genome was found almost identical (>98%) to the BCMV isolate RU1-OR (also pathotype VII) that did not induce necrotic symptoms in 'Jubila'. Inspection of the nucleotide sequences for BCMV isolates RU1-OR, RU1M, and US10 (all pathotype VII) and three closely related sequences of BCMV isolates RU1P, RU1D, and RU1W (all pathotype VI) revealed that RU1M is a product of recombination between RU1-OR and a yet unknown potyvirus. A 0.8-kb fragment of an unknown origin in the RU1M genome may have led to its ability to induce necrosis regardless of temperature in beans carrying the I gene. This is the first report of a BCMV isolate inducing temperature-insensitive necrosis in an I gene containing bean genotype.

Molecular and biological characterization of a recombinant isolate of potato virus Y from Mexico.

An isolate of potato virus Y (PVY), PVY-M3, was subjected to biological characterization on potato indicators and to whole-genome sequencing. PVY-M3 induced a local and systemic hypersensitive resistance (HR) response in potato cultivar Maris Bard expressing the Nz gene while inducing no HR in potato cultivars Desiree and King Edward, carrying Ny and Nc genes, respectively. These HR responses, combined with a lack of vein necrosis in tobacco, clearly defined PVY-M3 as an isolate of the PVY(Z) strain. Recombination analysis demonstrated that PVY-M3 had a typical European PVY(NTN) genome with three recombinant junctions, and PVY(N) and PVY(O) were identified as parents.

Molecular and Serological Typing of Potato virus Y Isolates from Brazil Reveals a Diverse Set of Recombinant Strains.

In Brazil, Potato virus Y (PVY) currently presents a significant problem for potato production, reducing tuber yield and quality. Recombinant tuber necrotic isolates of PVY had been reported to occur in the country but no systematic study of the PVY isolate diversity was conducted thus far. Here, a panel of 36 PVY isolates, randomly collected in Brazil from potato between 1985 and 2009, was subjected to a systematic molecular and serological typing using reverse-transcription polymerase chain reaction and a series of PVYO- and PVYN-specific monoclonal antibodies. The data collected were combined with biological characterization of the same isolates in tobacco. Of the 36 isolates tested, 3 were typed as PVYO, 10 as PVYN:O/N-Wi, 21 as PVYNTN, and 2 as "unusual" or inconclusive. Of the 10 isolates from the recombinant PVYN:O/N-Wi strain group, 1 isolate, MAF-VOY, was found to have an unusual serological profile identical to the nonrecombinant PVYO-O5 strain group. The 21 tested PVYNTN isolates included 1 isolate that did not induce vein necrosis in tobacco and 2 isolates with an unusual serological profile (i.e., displaying negative reactivity to one commercial PVYN-specific monoclonal antibody). Whole genome sequences were determined for four PVY isolates from Brazil, representing PVYO, PVYNTN, and PVYN-Wi strains. The genome of the MAF-VOY isolate was found to be recombinant, having characteristic N-Wi structure with two recombinant junctions and carrying a single mutation in the capsid protein at position 98, which led to an unusual O5 serological reactivity. Taken together, the data obtained suggest that the two recombinant strains, PVYNTN and PVYN:O/N-Wi, now are apparently dominant in the Brazilian potato crop. The data also suggest that recombinant isolates in Brazil often have unusual serological reactivity which may hamper their correct identification by conventional typing based on enzyme-linked immunosorbent assay.

Identification of the molecular make-up of the Potato virus Y strain PVY(Z): genetic typing of PVY(Z)-NTN.

Potato virus Y (PVY) strains were originally defined by interactions with different resistance genes in standard potato cultivars. Five distinct strain groups are defined that cause local or systemic hypersensitive responses (HRs) in genetic background with a corresponding N gene: PVY(O), PVY(N), PVY(C), PVY(Z), and PVY(E). The nucleotide sequences of multiple isolates of PVY(O) and PVY(N) differ from each other by ≈8% along their genomes. Additionally, complete genome sequences of multiple recombinant isolates are composed of segments of parental PVY(O) and PVY(N) sequences. Here, we report that recombinant isolate PVY-L26 induces an HR in potato 'Maris Bard' carrying the putative Nz gene, and is not recognized by two other resistance genes, Nc and Ny(tbr). These genetic responses in potato, combined with the inability of PVY-L26 to induce vein necrosis in tobacco, clearly define it as an isolate from the PVY(Z) strain group and provide the first information on genome structure and sequence of PVY(Z). The genome of PVY-L26 displays typical features of European NTN-type isolates with three recombinant junctions (PVY(EU-NTN)), and the PVY-L26 is named PVY(Z)-NTN. Three typical PVY(NTN) isolates and two PVY(N) isolates, all inducing vein necrosis in tobacco, were compared with PVY-L26. One PVY(NTN) isolate elicited HR reactions in Maris Bard, similar to PVY-L26, while two induced a severe systemic HR-like reaction quite different from the quasi-symptomless reaction induced by two PVY(N) isolates. 'Yukon Gold' potato from North America produced HR against several PVY(NTN) isolates, including PVY-L26, but only late and limited systemic necrosis against one PVY(N) isolate. Consequently, according to symptoms in potato indicators, both PVY(Z) and PVY(NTN) isolates appeared biologically very close and clearly distinct from PVY(O) and PVY(N) strain groups.

Genetic diversity of the ordinary strain of Potato virus Y (PVY) and origin of recombinant PVY strains.

The ordinary strain of Potato virus Y (PVY), PVY(O), causes mild mosaic in tobacco and induces necrosis and severe stunting in potato cultivars carrying the Ny gene. A novel substrain of PVY(O) was recently reported, PVY(O)-O5, which is spreading in the United States and is distinguished from other PVY(O) isolates serologically (i.e., reacting to the otherwise PVY(N)-specific monoclonal antibody 1F5). To characterize this new PVY(O)-O5 subgroup and address possible reasons for its continued spread, we conducted a molecular study of PVY(O) and PVY(O)-O5 isolates from a North American collection of PVY through whole-genome sequencing and phylogenetic analysis. In all, 44 PVY(O) isolates were sequenced, including 31 from the previously defined PVY(O)-O5 group, and subjected to whole-genome analysis. PVY(O)-O5 isolates formed a separate lineage within the PVY(O) genome cluster in the whole-genome phylogenetic tree and represented a novel evolutionary lineage of PVY from potato. On the other hand, the PVY(O) sequences separated into at least two distinct lineages on the whole-genome phylogenetic tree. To shed light on the origin of the three most common PVY recombinants, a more detailed phylogenetic analysis of a sequence fragment, nucleotides 2,406 to 5,821, that is present in all recombinant and nonrecombinant PVY(O) genomes was conducted. The analysis revealed that PVY(N:O) and PVY(N-Wi) recombinants acquired their PVY(O) segments from two separate PVY(O) lineages, whereas the PVY(NTN) recombinant acquired its PVY(O) segment from the same lineage as PVY(N:O). These data suggest that PVY(N:O) and PVY(N-Wi) recombinants originated from two separate recombination events involving two different PVY(O) parental genomes, whereas the PVY(NTN) recombinants likely originated from the PVY(N:O) genome via additional recombination events.

Immunodetection of Two Curtoviruses Infecting Sugar Beet.

Beet leafhopper-transmitted curly top virus is a serious problem in many different crops in the semiarid western United States, including sugar beet, tomatoes, and beans. Curly top is caused by a genetically diverse complex of phloem-limited curtoviruses. Due to the phloem restriction of curtoviruses and the lack of a convenient laboratory host-vector system for curly top virus propagation and purification, no commercial immunodetection tests are available for curtoviruses. Routine diagnostics for curly top rely either on visual symptoms or on polymerase chain reaction (PCR) tests. Lack of an enzyme-linked immunosorbent assay (ELISA) system is one of the factors hampering development and screening of the curly top resistant germplasm in, for instance, sugar beet and bean breeding programs. To fill in this gap, we developed an ELISA-based detection system for curtoviruses which utilizes virus-specific antibodies generated against bacterially expressed capsid protein (CP) of Beet mild curly top virus. Bacterially expressed CP was affinity purified and used as an antigen for antibody production in two animal species. Specificity of the resulting antisera was tested in Western blots and various triple-antibody sandwich (TAS)-ELISA formats with sugar beet, bean, and Nicotiana benthamiana leaf tissue. We demonstrate reliable detection of two curtoviruses in different crops in TAS-ELISA format, suitable for large-scale screening of germplasm in breeding programs.

A novel recombinant strain of Potato virus Y suggests a new viral genetic determinant of vein necrosis in tobacco.

A novel Potato virus Y (PVY) isolate, L26, recovered from a Frontier potato line was initially typed as a PVY(NTN) strain using multiplex RT-PCR and serological assays. However, L26 induced mosaic and mild vein clearing symptoms in tobacco rather than vein necrosis characteristic of the PVY (NTN) strain. The whole genome sequence was determined for L26 and two other PVY(NTN) isolates, HR1 and N4, from Idaho that did induce vein necrosis in tobacco. The sequence of all three isolates was similar to typical European PVY(NTN) isolates that contain three recombination junctions in their genome. The sequence of the L26 genome was nearly identical to the genomes HR1, N4, and to a previously characterized PVY(NTN) isolate, 423-3, differing by only five nucleotides in the entire ca. 9.7-kb genome, only one resulting in a corresponding amino acid change, D-205 to G-205 in the central region of HC-Pro. Two "signature" amino acid residues, thought involved in induction of the vein necrosis syndrome in tobacco, K-400 and E-419, were present in the C-terminal region of HC-Pro of all three isolates. Multiple alignment of the whole genome sequences of L26 and other PVY(NTN) isolates whose phenotype in tobacco has been reported, suggests that a single nucleotide change (A-1,627 to G-1,627) resulting in the single amino acid change (D-205 to G-205) in the HC-Pro cistron of L26 correlates with the loss of the vein necrosis phenotype in tobacco. Secondary structure modeling of the HC-Pro protein predicts the G-205 residue, and the previously identified residues K-400 and E-419, would all be located on the exposed surface of the protein. Taken together, these data suggest that the vein necrosis genetic determinant of PVY in tobacco is complex and includes other element(s), in addition to the C-terminal fragment of HC-Pro.

Plant based HIV-1 vaccine candidate: Tat protein produced in spinach.

The HIV-1 Tat protein has been recently explored as a prospective vaccine candidate with broad, subtype non-specific action. We approached the problem of delivery of Tat through the mucosal route by expressing Tat in an edible plant. The tat gene was assembled from synthetic overlapping oligonucleotides, and was subsequently cloned into a plant virus-based vector tobacco mosaic virus (TMV). Spinach plants inoculated with the Tat-producing constructs were collected and fed to mice 7-14 days post inoculation. DNA vaccinations were performed using a gene gun. Codon optimization of the Tat gene expressed in spinach plants resulted in several-fold yield increase as detected in immunoblots, and did not cause severe symptoms in inoculated plants. Mice were fed with the Tat-producing or control vector-inoculated spinach. After three feedings, 1 week apart, 1g per mice, no differences were detected in the growth rate or behavior of the animals fed with these three types of spinach. None of the animals developed measurable Tat antibodies. Following DNA vaccination, however, mice having previously received oral Tat developed higher antibody titers to Tat than did the controls, with the titers peaking at 4 weeks post-vaccination. Codon optimization allows production of up to 300-500 microg of Tat antigen per 1 g of leaf tissue in spinach using a plant virus-based expression system. The plant produced Tat does not seem to have any apparent adverse effect on mice growth or behavior, when fed with spinach for 4 weeks. ELISA data suggested that oral Tat primed for the development of Tat antibodies when mice were subsequently vaccinated with plasmid DNA designed for Tat expression.