Separation of Slovenian isolates of PVY(NTN) from the North American isolates of PVY(N) by a 3-primer PCR

Comparison of Mineral Oil, Insecticidal, and Biopesticide Spraying Regimes for Reducing Spread of Three Potato virus Y Strains in Potato Crops

In-field management of Potato virus Y (PVY) faces challenges caused by the changing availability and environmental acceptability of chemical agents to control aphid vectors of the virus and by proliferation of PVY strains with different symptoms and rates of spread. From 2018 to 2020, foliar spray treatments were compared in field experiments in New Brunswick, Canada, to measure effectiveness at reducing spread of PVY^O, PVY^N:O, and PVY^NTN strains. Mineral oil, insecticide, combined oil and insecticide spray, and a biopesticide (i.e., LifeGard WG) were compared. Insecticide-only and mineral oil-only treatments were not effective, but several combined oil and insecticide treatments and biopesticide treatments significantly reduced PVY spread. The biopesticide was proportionately more effective with recombinant PVY^N:O and PVY^NTN strains, possibly by exciting the plant's hypersensitive resistance response, caused naturally only in cultivar 'Goldrush' by PVY^O. Pesticide residue analysis showed that mineral oil increased the retention of pyrethroid insecticide in the potato foliage longer than with insecticide applied alone, which may explain the beneficial synergistic effect of combined sprays for reducing PVY spread. Tuber yields were generally unchanged in chemical insecticide treatments but were slightly lower in biopesticide treatment. The cost per PVY treatment was competitive across all effective treatments, including biopesticide; however, there was some revenue loss from lower yield with the biopesticide. This biopesticide is certified organic, however, and thus a small premium on the price for organic production could offset this yield deficit.

Assessment of SNaPshot and single step RT-qPCR methods for discriminating Potato virus Y (PVY) subgroups

Potato virus Y (PVY) is the most important virus infecting potato (Solanum tuberosum), causing potato tuber necrotic ringspot disease (PTNRD), with a great impact on seed potato production. Numerous PVY strain groups with different pathogenicity and economical impact are distributed worldwide. Tools for accurate and reliable detection and discrimination of PVY strain groups are therefore essential for successful disease management. Two state of the art characterization tools based on detecting molecular markers - RT-qPCR (Kogovsek et al., 2008) and SNaPshot (Rolland et al., 2008) - were assessed for their ability to assign PVY accurately to the correct group. The results were validated by bioassay, ELISA and in silico sequence analysis. The spectrum of PVY strain groups distinguished by SNaPshot is broader than that by RT-qPCR. However, the latter was more reliable in discriminating the PVY(NTN) group members, known for their ability to induce PTNRD on selected potato cultivars. The difference in discrimination precision was due to different molecular markers being targeted by RT-qPCR and SNaPshot. Both tools use genotypic markers for detecting PVY(NTN) strain groups. Future development, however, should be focused on identifying the genomic determinants of the tuber necrosis property. Until then, the RT-qPCR and SNaPshot methods remain the most powerful diagnostic tools for detecting the PVY subgroup isolates found in Europe.

Genomic variability in potato virus M and the development of RT-PCR and RFLP procedures for the detection of this virus in seed potatoes

Potato virus M (PVM, Carlavirus) is considered to be one of the most common potato viruses distributed worldwide. Sequences of the coat protein (CP) gene of several Canadian PVM isolates were determined. Phylogenetic analysis indicated that all known PVM isolates fell into two distinct groups and the isolates from Canada and the US clustered in the same group. The Canadian PVM isolates could be further divided into two sub-groups. Two molecular procedures, reverse transcription - polymerase chain reaction (RT-PCR) and restriction fragment length polymorphism (RFLP) were developed in this study for the detection and identification of PVM in potato tubers. RT-PCR was highly specific and only amplified PVM RNA from potato samples. PVM RNAs were easily detected in composite samples of 400 to 800 potato leaves or 200 to 400 dormant tubers. Restriction analysis of PCR amplicons with MscI was a simple method for the confirmation of PCR tests. Thus, RT-PCR followed by RFLP analysis may be a useful approach for screening potato samples on a large scale for the presence of PVM.

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.

Discussion paper: The naming of Potato virus Y strains infecting potato

Potato virus Y (PVY) strain groups are based on host response and resistance gene interactions. The strain groups PVY(O), PVY(C) and PVY(N) are well established for the isolates infecting potato in the field. A switch in the emphasis from host response to nucleotide sequence differences in the virus genomes, detection of isolates recombining sequences of different strains, and the need to recognize isolates that cause necrotic symptoms in potato tubers have led to the assignment of new acronyms, especially to isolates of the PVY(N) strain group. This discussion paper proposes that any newly found isolates should be described within the context of the original strain groups based on the original methods of distinguishing strains (i.e., tobacco and potato assays involving use of 'differential' potato cultivars). Additionally, sequence characterization of the complete genomes of isolates is highly recommended. However, it is acceptable to amend the names of PVY isolates with additional, specific codes to show that the isolate differs at the molecular, serological or phenotypic level from the typical strains within a strain group. The new isolates should preferably not be named using geographical, cultivar, or place-association designations. Since many new variants of PVY are being discovered, any new static classification system will be meaningless for the time being. A more systematic investigation and characterization of PVY from potato at the biological and molecular levels should eventually result in a biologically meaningful genetic strain concept.

Rapid identification of potato virus Y strains by one-step triplex RT-PCR

A one-step triplex RT-PCR method was characterised that allows rapid, strain-specific detection of potato virus Y (PVY) occurring on potato: PVY(N), PVY(O), PVY(NTN) (recombinant isolates), PVY(N)Wi and PVY(C). Three specific primer pairs were designed on aligned PVY sequences available from genomic data banks. The specificity of the selected primers was first examined by simplex RT-PCR with a large number of PVY reference isolates. Two fragments of 0.44 and 1.11kb were amplified for PVY(N) and non-recombinant PVY(NTN) isolates, two fragments of 0.53 and 0.66kb for PVY(O) isolates, a single fragment of 0.44kb for recombinant PVY(NTN) isolates, a 0.66kb fragment for PVY(C) isolates and a 0.53kb fragment for PVY(N)Wi isolate. The primers were then combined in a one-step triplex RT-PCR reaction, optimised stepwise and validated with the reference isolates. The great similarity between the genomes of PVY(N) and non-recombinant PVY(NTN) prevented their differentiation using this method. No fragments were amplified with samples infected by non-related potato viruses, as well as with samples from healthy tobacco and potato plants. The one-step triplex RT-PCR described here fastens specific detection of PVY strains that are otherwise only distinguishable by combined serological and biological assays.

Differentiation of Potato virus Y strains using improved sets of diagnostic PCR-primers

Potato virus Y (PVY) is one of the most important viruses of potato world-wide, several strain groups are recognized. In the past two decades, novel PVY variants have appeared causing necrotic symptoms on potato tubers. Implicated are two groups of recombinant strains: PVY(N)W and PVY(NTN), and NA-PVY(NTN). While the first two are recombinants between PVY-N- and O-strains the latter is a recombinant between an N-strain and an unknown PVY strain or other Potyvirus. Available biological and molecular data on PVY suggest that classification of PVY strains has to be revised. Some drawbacks have been found with recently published primers used in RT-PCR based differentiation of PVY strains as some defined isolates could not be identified correctly. Consequently we developed new primers using both recently available sequences and newly generated complete sequences of PVY strains. The reliability of these newly developed primers and procedures was successfully demonstrated on nearly 100 biologically and serologically characterised PVY isolates.

The Occurrence of PVYO, PVYN, and PVYN:O Strains of Potato virus Y in Certified Potato Seed Lot Trials in Washington and Oregon

Totals of 960 and 286 certified potato seed lots from locations across North America were planted in trials in Washington and Oregon, respectively, in 2001 to 2003 and tested for strains of Potato virus Y (PVY). The incidence of PVY^O-infected lots averaged 16.4 and 25.9% in the Washington and Oregon trials, respectively. There was a general trend of increasing incidence of the PVY^O, PVY^N:O, and PVY^N strains during this period, as evidenced by more infected cultivars, sites of seed origin, and number of seed growers providing infected seed lots. In particular, there was a dramatic increase in seed lots with the PVY^N:O strain from 2002 to 2003. PVY^N:O, in contrast to PVY^O, which only causes yield reduction, also causes internal and external damage to tubers, making them unmarketable. In 2003, PVY^N:O occurred in seed lots originating in eight states and three Canadian provinces. The increased incidence of PVY^N:O was likely due to the difficulty in differentiating this strain from PVY^O. The prevalence of PVY in potato seed lots documented herein poses a threat to potato production in the United States and suggests that current measures to reduce the incidence of this virus are inadequate.

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.

Specific differentiation of recombinant PVY(N:O) and PVY(NTN) 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.

Tagging of viral RNA transcripts with strain-specific oligonucleotides: characterization and application

Binding('tagging') of a virus-specific oligonucleotide 'sticker' to RNA transcripts copied from PCR products caused retardation of transcript mobility in gel. This enables detection of specific sequences within the RNA transcripts, and a virus strain (PVY(NTN)) could thus be positively identified. We have demonstrated further that oligonucleotides that contained virus sequences originated from different genomic locations varied in their inhibitory effect on the rate of transcript migration in gel; thus, the most effective oligonucleotide could be chosen. Combinations of different strain-specific oligonucleotides had additive retarding effects on transcript migration. The conditions for annealing oligonucleotides to the RNA transcripts were studied, including concentrations of oligonucleotides and salt. A higher electrophoresis temperature (up to 45 degrees C) reduced the gel retardation phenomena, which indicated a conformation mechanism. The applicability of 'tagging' of RNA transcripts with a strain-specific oligonucleotide for virus strain differentiation is discussed.

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 (PVY^O) and tobacco veinal necrosis strains (PVY^N/NTN) indicated that 37.5% contained PVY^O and 63.5% contained PVY^N-type isolates. Analysis of the PVY^N-type samples using three monoclonal antibodies (MAbs) showed that all reacted with only the PVY^O MAbs and not with the PVY^N-specific MAb. Partial nucleotide sequences of both ends of PVY-RNA showed that the PVY^N-type isolates resembled those reported in 1996 from Manitoba. These isolates are designated as PVY^N:O. In view of the increased incidence of PVY^N:O in one production area, seed tubers imported from other provinces of Canada and the neighboring United States were analyzed for PVY^N:O. The PVY^N:O was detected in imported seeds from Minnesota, Montana, and North Dakota.

The detection of recombinant, tuber necrosing isolates of Potato virus Y (PVY(NTN)) using a three-primer PCR based in the coat protein gene

A simple and reliable procedure for reverse transcription-polymerase chain reaction (RT-PCR) detection and strain differentiation of Potato virus Y (PVY) was developed. Three primers were designed within the coat protein (CP) and nuclear inclusion protein b (NIb) region, exploiting a single base polymorphism identified as being present in all the recombinant PVY(NTN) isolates published. Samples infected with PVY produce a single band of 569 bp, while isolates belonging to PVY(NTN) strain give an additional band of 334 bp. The technique was tested on a collection of well-characterised isolates of PVY from a range of strains and was found to detect all of the isolates reported as belonging to the PVY(NTN) strain. All of the isolates detected possess a recombination event within the coat protein. Further sequence analysis revealed that all the recombinant PVY(NTN) isolates reported thus far would be detected using this assay, whilst isolates thought to be PVY(NTN) that do not possess the coat protein recombination event would not be detected.

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).

Probable geographical grouping of PVY(N) and PVY(NTN) based on sequence variation in P1 and 5'-UTR of PVY genome and methods for differentiating North American PVY(NTN)

An increasing number of countries in recent years have reported the occurrence of potato tuber necrotic ringspot disease (PTNRD), caused by tobacco veinal necrosis strain of Potato virus Y (PVY(N)), belonging to the sub-group tuber necrosis (PVY(NTN)). Methods for the differentiation of PVY(NTN), based on primer sequences often detect isolates of European (EU) type but not the North American (NA) type. To resolve this problem, the nucleotide sequence of 5'-untranslated region (5'-UTR) and the P1 gene of 11 isolates of PVY(N) and PVY(NTN) from the European Union and North America was determined. Sequence comparison and phylogenetic analysis of 5'-UTR and P1 region indicated that PVY(N) isolates from the European Union and North America formed their own separate groups. Intra-group sequence identity for all except one was over 98%, as opposed to the inter-group identity of 90%. Additionally, the PVY(NTN) isolates from the European Union and North America clustered with their respective PVY(N) isolates. This indicates a possible evolution of PVY(NTN) isolates from the PVY(N) isolates of a geographical region. With this information of regional relationships of PVY(NTN) and PVY(N) isolates, two approaches were developed based on a competitive RT-PCR and a restriction pattern, for the differentiation of NA-PVY(NTN) from the local PVY(N) and from EU-PVY(NTN). Thus sequencing of the P1 gene and use of competitive RT-PCR approach could be applicable for determining the possible origin of new occurrences of PVY(NTN) from other geographical regions.

The detection of tuber necrotic isolates of Potato virus Y, and the accurate discrimination of PVY(O), PVY(N) and PVY(C) strains using RT-PCR

Potato tuber necrotic ringspot disease (PTNRD) is a damaging disease of potatoes, causing unsightly necrotic rings on the surface of tubers. The causal agent is thought to be tuber necrotic isolates of Potato virus Y, known as PVY(NTN). The disease spoils tubers for processing and table use, and the lack of a diagnostic method makes control especially difficult. The development of an RT-PCR assay for the reliable detection of PVY(NTN) and discrimination of all the main strains of PVY (PVY(O), PVY(N) and PVY(C)) is described. An assay was developed, exploiting a recombination site in the coat protein of PVY(NTN), allowing more reliable diagnosis of these isolates. Although the conserved nucleotide differences observed between the strains was very small, competitive PCR and mutagenically separated PCR were both employed in the development of a robust assay. The assay was found to be more reliable than the most commonly used RT-PCR method, and should prove to be an important tool in the confirmation of symptoms and for the detection of PVY(NTN) in symptomless tissue, in disease surveys and seed health schemes.

Development of a multiplex AmpliDet RNA assay for simultaneous detection and typing of potato virus Y isolates

A multiplex AmpliDet RNA assay was developed for the specific detection of potato virus Y (PVY), and for the differentiation of the PVY(N), PVY(O/C) strains and the tuber necrotic isolates (PVY(NTN)). The assay is based on the generic amplification of a region within the coat protein coding region of all known PVY isolates by nucleic acid sequence-based amplification (NASBA) and strain-specific detection by molecular beacons. PVY(NTN)-specific diagnosis is achieved by detecting PVY(N) and PVY(O)-specific sequences flanking a recombination site that is associated with the tuber necrotic pathotype. The assay exhibited good specificity toward the various PVY strains in both single and mixed infections. The technique was validated by the use of 47 PVY isolates originating from six countries. The results of the AmpliDet RNA assay were identical or consistent with those of biological characterisation in the decisive majority of cases.

Analysis of the nucleotide sequence of the coat protein and 3'-untranslated region of two Brazilian Potato virus Y isolates

Two Brazilian Potato virus Y (PVY) isolates were biologically characterized as necrotic (PVY-NBR) and common (PVY-OBR) based upon symptoms on test plants. Additional characterization was performed by sequencing a cDNA corresponding to the 3' terminal region of the viral genome. The sequence consisted of 195 nucleotides (nt) coding part of the nuclear inclusion body b (NIb) gene, 804 nt of the coat protein (CP) gene, and 328 nt (PVY-OBR) or 326 nt (PVY-NBR) of the 3'-untranslated region (UTR). Translation of the sequence resulted in one single open reading frame with part of the NIb and a CP of 267 amino acids. The two isolates shared 95.1% similarity in the CP amino acid sequence. The CP and the 3'-UTR sequence of the Brazilian isolates were compared to those of other PVY isolates previously reported and unrooted phylogenetic trees were constructed. The trees revealed a separation of two distinct clusters, one comprising most of the common strains and the other comprising the necrotic strains. PVY-OBR was clustered in the common group and PVY-NBR in the necrotic one.

RT-PCR detection and identification of three species of cucumoviruses with a genus-specific single pair of primers

Reverse transcription and polymerase chain reaction (RT-PCR) was used for detection and identification of three cucumoviruses (cucumber mosaic virus, CMV; peanut stunt virus, PSV; tomato aspermy virus, TAV) in various plants sources with a single pair of primers, designed as CPTALL-3 and CPTALL-5. The pair of cucumovirus genus-specific primers that flank the coat protein gene were designed and used to amplify a DNA fragment of approximately ranging from 938 to 966 bp. The RT-PCR with the set of primers specifically amplified the target size of DNA fragment in all the tested cucumoviruses (CMV S-IA, S-IB and S-II, PSV and TAV). No DNA product of any length was produced when brome mosaic virus or tobacco mosaic virus RNA was used as templates. The cucumoviruses examined were differentiated by PCR-restriction fragment length polymorphism with different enzymes. This indicates that the designed primers are only specific for the cucumoviruses and useful for reliable information of identification of members of the Cucumovirus genus.

Development of the molecular methods for potato virus and viroid detection and prevention

Potato is the fourth most important food crop in the world and it forms the diet of a billion consumers in developing countries, where potato production is increasing rapidly. However, potato virus diseases in developing countries are one of the major causes of lower yields. Their control requires the development of appropriate virus-detection and seed-production technologies for the region. Recent progress in developing nucleic acid based virus detection methods are reviewed. Refinements of the protocols applicable to the laboratories located in seed producing areas are discussed. Nucleic acid spot hybridization (NASH) and reverse transcription polymerase chain reaction (RT-PCR) methods are described for the detection of viruses and viroids in dormant seed tubers and insect vectors. Although the potato crop is susceptible to over 25 virus and viroid diseases, only universally economically important viruses have been dealt with here. The progress of pathogen-derived resistance for the control of potato virus diseases is elaborated, and the results of field tests indicate their feasibility in virus control.Key words: dot-blot, spot-hybridization, reverse transcription, polymerase chain reaction, transgenic plants.

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.