Rudra P. Singh

Diversity Among Potato virus Y Isolates Obtained from Potatoes Grown in the United States

ABSTRACT Potato field isolates (Solanum tuberosum) of Potato virus Y (PVY) collected from the midwestern and western United States were characterized using serological, molecular, and biological assays. PVY field isolates were grouped into the previously defined categories: PVY(O), European PVY(NTN), North American PVY(NTN), and PVY(N:O) recombinant and four previously undefined groups. Studies reported here agree with published reports from Europe and elsewhere in North America as PVY isolates capable of causing veinal necrosis in tobacco indicator plants appear in high frequency. In contrast to European experiences, PVY tuber necrosis isolates have a PVY(O) coat protein rather than that of PVY(N). Several PVY(N:O) recombinant isolates induced potato tuber necrotic ringspot disease (PTNRD) in the highly susceptible potato cv. Yukon Gold. The PTNRD symptoms produced by these PVY(N:O) recombinants were atypical compared with lesions found on the same cultivar infected with either the European or North American PVY(NTN) isolates. These PVY(N:O) isolates produced a roughly circular, sunken necrotic lesion on the surface of the tuber instead of the typical external sunken ring pattern displayed by PVY(NTN) isolates. This study establishes the complex nature of PVY populations within the U.S. potato industry and clearly demonstrates the diverse nature of PVY in the United States.

A new approach for the simultaneous differentiation of biological and geographical strains of Potato virus Y by uniplex and multiplex RT-PCR.

Two strains of Potato virus Y (PVY), the common (PVY(O)) and the tobacco veinal necrosis (PVY(N)) have been known for decades. More recently, a tuber ringspot necrosis (PVY(NTN)), and several recombinants of PVY(O) and PVY(N) (designated here as PVY(N:O)) have been described. Further, the PVY(N) group of strains have been assigned to two geographical subgroups of European (EU) PVY(N/NTN) and the North American (NA) PVY(N/NTN). The evolution of new PVY(N) strains, has complicated the diagnosis, which requires a combination of bioassay, serological and molecular assays. To simplify the identification and differentiation of various PVY(N) strain groups, a competitive (single antisense and multiple sense primers) reverse transcription-polymerase chain reaction (RT-PCR) was used, making use of minor differences in the variable region part of the PVY genome. Specifically, primers based on small variations in nucleotide stretches of P1 gene permitted a broad range separation of PVY(O) and PVY(N) groups and the specific detection of strain subgroups. The primer pairs designed for identifying PVY(O), EU-PVY(N/NTN), NA-PVY(N) and NA-PVY(NTN) are described. Primer pairs can be used in a uniplex (single pair of primer) or multiplex (duplex, tetraplex or pentaplex) competitive RT-PCR, allowing simultaneous testing for any combination of PVY(O), EU-PVY(N/NTN), NA-PVY(N) and NA-PVY(NTN).

Specific differentiation of recombinant PVYN:O and PVYNTN isolates by multiplex RT-PCR

The recombinant isolates of tobacco veinal necrotic strain of Potato virus Y (PVYN) and potato tuber necrotic group (PVY(NTN)) contain segments of the PVYO and the PVY(N) genome. Three major recombinant junctions (RJ) are present in the genome of the recombinant PVY(NTN) at sites HC/Pro-P3, 6K2-NIa, and the C-terminal region of CP gene and one RJ at HC/Pro-P3 site in some recombinant PVYN isolates (termed PVY(N:O)). Protocols for specific differentiation of the recombinant PVY(NTN) and PVY(N:O) from the non-recombinant PVYN are described. Specific primer pairs were designed to target the three RJs so that sense and antisense primers completely matched the nucleotide sequences at either side of the RJ. In a uniplex reverse transcription-polymerase chain reaction (RT-PCR), the first primer pair amplified a fragment of 641bp from the recombinant PVY(NTN) and PVY(N:O). The second and third primer pairs exclusively amplified fragments of 448 and 290bp, respectively from the recombinant PVY(NTN). In a multiplex (triplex) RT-PCR, when all three primer pairs were used simultaneously, the three fragments (641, 448 and 290bp) were amplified exclusively from the recombinant PVY(NTN), while only one fragment (641bp) was amplified from the PVY(N:O) isolates, clearly differentiating the two recombinant isolates. No amplification was observed from the non-recombinant PVY, including PVYO and North American (NA)-PVY(N/NTN). For further improvement of the multiplex RT-PCR, effects of cDNA preparation using specific antisense primers, random primers or oligo(dT) plus random primers were investigated. The cDNA prepared by random primer plus oligo(dT) increased the overall band intensity.

Detection of stylet-borne and circulative potato viruses in aphids by duplex reverse transcription polymerase chain reaction

A reverse transcription polymerase chain reaction (RT-PCR) assay was designed to amplify stylet-borne potato virus Yo (PVYo) in aphids using primers located in the viral capsid gene. A 480 bp long product was detected in aphids exposed to PVYo-infected potato plants. Approximately 40% of Myzus persicae and 15% of Aphis nasturtii exposed briefly to PVYo-infected plants acquired the virus. This rate of acquisition by both species of aphids was typical of our earlier observation of the virus transmission tests. No significant difference in virus detection was observed whether the aphids were tested immediately after exposure to virus sources or stored for up to 45 days in ethanol at room temperature. The addition of a second pair to primers located in the capsid gene of circulative potato leafroll virus (PLRV) allowed simultaneous amplification of two viruses (duplex RT-PCR) in single aphids. Acquisition of PVYo by the aphids already viruliferous with PLRV was significantly reduced, compared to aphids not carrying PLRV. Duplex RT-PCR for PVYo and PLRV could be applied to analyze aphids collected from the field to ascertain the relative presence of both viruses in a single test.

Possible Escape of a Recombinant Isolate of Potato virus Y by Serological Indexing and Methods of its Detection

Surveys of commercial and seed potato fields for virus diseases (1998 to 2002) in Manitoba established that Potato virus Y (PVY) is of concern in seed potato production. To determine the prevalence of PVY strains, PVY-infected tubers identified by reverse transcription-polymerase chain reaction (RT-PCR) from surveys (2000 to 2001) were grown for symptom expression and strain characterization by strain-specific RT-PCR, bioassays, and serological assays. Of the samples collected (2000 to 2001) and tested by RT-PCR, 4.0% contained PVY. Further analysis of the PVY-positive samples by a duplex RT-PCR facilitating the simultaneous detection of common (PVYO) and tobacco veinal necrosis strains (PVYN/NTN) indicated that 37.5% contained PVYO and 63.5% contained PVYN-type isolates. Analysis of the PVYN-type samples using three monoclonal antibodies (MAbs) showed that all reacted with only the PVYO MAbs and not with the PVYN-specific MAb. Partial nucleotide sequences of both ends of PVY-RNA showed that the PVYN-type isolates resembled those reported in 1996 from Manitoba. These isolates are designated as PVYN:O. In view of the increased incidence of PVYN:O in one production area, seed tubers imported from other provinces of Canada and the neighboring United States were analyzed for PVYN:O. The PVYN:O was detected in imported seeds from Minnesota, Montana, and North Dakota.

Detection of multiple potato viruses using an oligo(dT) as a common cDNA primer in multiplex RT-PCR

A novel usage of multiplex reverse transcription polymerase chain reaction (m-RT-PCR) for simultaneous detection of multiple viruses is reported. By use of an oligo(dT), as a common primer, nearly full-length cDNAs can be synthesized. Furthermore, combining an oligo(dT) primer with a specific antisense primer can be used to simultaneously prime reverse transcription of both polyadenylated and non-polyadenylated RNAs. Four viral genera including five potato viruses [(carlavirus (PVS), polerovirus (PLRV), potexvirus (PVX), potyvirus (PVA and PVY))] and a viroid genus including a viroid genome (pospiviroid (PSTVd)) were used to develop various formats of m-RT-PCR. In artificially created viral RNA mixtures, all six RNA pathogens were detected successfully by uniplex- and m-RT-PCR. In naturally infected field grown tubers, m-RT-PCR detected infection of two to three viruses, which were present in the tubers.

Sodium sulphite inhibition of potato and cherry polyphenolics in nucleic acid extraction for virus detection by RT-PCR.

Phenolic compounds from plant tissues inhibit reverse transcription-polymerase chain reaction (RT-PCR). Multiple-step protocols using several additives to inhibit polyphenolic compounds during nucleic acid extraction are common, but time consuming and laborious. The current research highlights that the inclusion of 0.65 to 0.70% of sodium sulphite in the extraction buffer minimizes the pigmentation of nucleic acid extracts and improves the RT-PCR detection of Potato virus Y (PVY) and Potato leafroll virus (PLRV) in potato (Solanum tuberosum) tubers and Prune dwarf virus (PDV) and Prunus necrotic ringspot virus (PNRSV) in leaves and bark in the sweet cherry (Prunus avium) tree. Substituting sodium sulphite in the nucleic acid extraction buffer eliminated the use of proteinase K during extraction. Reagents phosphate buffered saline (PBS)-Tween 20 and polyvinylpyrrolidone (PVP) were also no longer required during RT or PCR phase. The resultant nucleic acid extracts were suitable for both duplex and multiplex RT-PCR. This simple and less expensive nucleic acid extraction protocol has proved very effective for potato cv. Russet Norkotah, which contains a high amount of polyphenolics. Comparing commercially available RNA extraction kits (Catrimox and RNeasy), the sodium sulphite based extraction protocol yielded two to three times higher amounts of RNA, while maintaining comparable virus detection by RT-PCR. The sodium sulphite based extraction protocol was equally effective in potato tubers, and in leaves and bark from the cherry tree.

Factors affecting detection of PVY in dormant tubers by reverse transcription polymerase chain reaction and nucleic acid spot hybridization

A reverse transcription polymerase chain reaction (RT-PCR) protocol was developed using two 20-mer primers located in nuclear inclusion genes NIa and NIb of potato virus Y (PVY). A 1017 bp PCR-product was detected in dormant potato tubers, infected with PVY(O), but not in tubers from healthy plants. The PCR product was specific to PVY, as determined by Southern blot detection by hybridization with a PVY(O)-specific probe. As little as 1 pg of purified PVY(O)-RNA can be detected after RT-PCR amplification. The presence of phenolics or polysaccharides in tuber nucleic acids inhibited PVY(O) amplification, which was eliminated by diluting nucleic acid preparations prior to cDNA synthesis, modifying the nucleic acid extraction procedure by isopropanol precipitation and using phosphate-buffered saline-Tween in the cDNA mix. Potato cultivars differed in PVY(O) concentration in tubers as much as 128-fold. Tuber parts used for nucleic acid extractions were important in potato cultivars with low virus titres and did not result in reduced detection of PVY(O) by both nucleic acid spot hybridization and RT-PCR, but RT-PCR band intensity was lower at longer storage periods. The primer pair developed in this study exhibited broad specificities with field isolates from Peru, Scotland and North America.

Detection of potato leafroll virus in single aphids by the reverse transcription polymerase chain reaction and its potential epidemiological application

A reverse transcription and polymerase chain reaction (RT-PCR) system was developed using two 20-mer primers located in the potato leafroll virus (PLRV) capsid gene. A 336-bp PCR product was detected from aphids (Myzus persicae) which had been fed on PLRV-infected plants. The PCR band was specific to PLRV as determined by Southern blots and detection by a PLRV-specific probe. As little as 5 min exposure of aphids to PLRV-infected leaves resulted in the presence of PLRV-specific bands in 13% of aphids. However, the percentage of PLRV-positive aphids increased with longer exposure to infected sources and reached 90% after 3-4 days of feeding. PLRV can be detected from a single viruliferous aphid or a single viruliferous aphid combined with up to 29 non-viruliferous aphids. PLRV can be detected from freshly collected aphids, those stored at -70 degrees C, or those stored in 70% ethanol at room temperature for extended periods. This method is applicable to assess the viruliferous nature of aphids caught in yellow-pan traps during the growing season or stored for over a year.

Reverse-transcription polymerase chain reaction for the detection of viruses from plants and aphids

A reverse transcription polymerase chain reaction (RT-PCR) protocol used for the detection of potato viruses in dormant tubers and leaves and in an aphid vector is described. Problems in plant sample preparation from different hosts, uneven distribution or low concentration of viruses and the presence of PCR inhibitors in plant extracts are discussed and various ways to eliminate their effect are described. Using Potyviridae viruses, it has been shown that RT-PCR in various modified forms can be used to differentiate viruses at the level of family, genus, species, strains and their subtypes or serotypes. The specificity of primer pairs and PCR modifications has been used to separate closely related potato viruses A and PVY strains (PVY(O), PVY(N) and PVY(NTN)) from a known mixture.