Detection of a New and Unusual Isolate of Plum pox virus in Plum (Prunus domestica)

The global phylogeny of Plum pox virus is emerging

The 206 complete genomic sequences of Plum pox virus in GenBank (January 2019) were downloaded. Their main open reading frames (ORF)s were compared by phylogenetic and population genetic methods. All fell into the nine previously recognized strain clusters; the PPV-Rec and PPV-T strain ORFs were all recombinants, whereas most of those in the PPV-C, PPV-CR, PPV-CV, PPV-D, PPV-EA, PPV-M and PPV-W strain clusters were not. The strain clusters ranged in size from 2 (PPV-CV and PPV-EA) to 74 (PPV-D). The isolates of eight of the nine strains came solely from Europe and the Levant (with an exception resulting from a quarantine breach), but many PPV-D strain isolates also came from east and south Asia and the Americas. The estimated time to the most recent common ancestor (TMRCA) of all 134 non-recombinant ORFs was 820 (865-775) BCE. Most strain populations were only a few decades old, and had small intra-strain, but large inter-strain, differences; strain PPV-W was the oldest. Eurasia is clearly the 'centre of emergence' of PPV and the several PPV-D strain populations found elsewhere only show evidence of gene flow with Europe, so have come from separate introductions from Europe. All ORFs and their individual genes show evidence of strong negative selection, except the positively selected pipo gene of the recently migrant populations. The possible ancient origins of PPV are discussed.

Aphid Transmission of the Ontario Isolate of Plum Pox Virus

Utilization of timed virus acquisition access probes in studies of plum pox virus (PPV) transmission by aphids demonstrated that endemic species transmitted the virus readily from plum, Prunus domestica (L.) Batsch; peach, P. persica (L.); or dwarf flowering almond, P. glandulosa Thunberg., to peach seedlings. The green peach aphid, Myzus persicae (Sulzer), was shown to be the most efficient vector. Acquisition of virus by green peach aphids from infected peach leaves resulted in 18-28% infected peach seedlings, while aphids previously fed on infected leaves of plum transferred virus to 36% of peach seedlings. Although the spirea aphid, Aphis spiraecola (Patch), was a less efficient vector than M. persicae it is perhaps more important for the spread of PPV due to its greater abundance and occurrence earlier in the season when peach trees are thought to be more susceptible to infection. Virus transmission rates varied depending on the virus source and healthy test plant species. In contrast to many previous studies, aphid inoculation of the experimental host Nicotiana benthamiana Domin occurred at a low rate, never exceeding 4%. Acquisition of PPV by M. persicae from infected peach fruit was greatly reduced compared with acquisition from leaves. The results of this research indicate that the Ontario isolate of PPV-D is readily transmissible by aphids to peach and natural spread of the virus needs to be considered in future management or eradication programs.

Analysis of the complete genome of a virus associated with twisted leaf disease of cherry reveals evidence of a close relationship to unassigned viruses in the family Betaflexiviridae

The genome of a virus associated with cherry twisted leaf disease (CTLaV, isolate ZH) was sequenced and consists of 8431 nucleotides, excluding a poly(A) tail at the 3' end. Genome analysis shows that CTLaV-ZH represents a new and distinct species and has a genome organization similar to those of unassigned viruses in the family Betaflexiviridae. The CTLaV-ZH genome has five open reading frames (ORFs), with putative ORFs within ORF2 and ORF5, identified as ORF2a and ORF5a, respectively. The AUG start codons of ORF2a and ORF5a are in contexts suitable for efficient translation, with appropriate stop codons in frame.

Complete genome sequence of a novel Plum pox virus strain W isolate determined by 454 pyrosequencing

The near-complete (99.7 %) genome sequence of a novel Russian Plum pox virus (PPV) isolate Pk, belonging to the strain Winona (W), has been determined by 454 pyrosequencing with the exception of the thirty-one 5'-terminal nucleotides. This region was amplified using 5'RACE kit and sequenced by the Sanger method. Genomic RNA released from immunocaptured PPV particles was employed for generation of cDNA library using TransPlex Whole transcriptome amplification kit (WTA2, Sigma-Aldrich). The entire Pk genome has identity level of 92.8-94.5 % when compared to the complete nucleotide sequences of other PPV-W isolates (W3174, LV-141pl, LV-145bt, and UKR 44189), confirming a high degree of variability within the PPV-W strain. The isolates Pk and LV-141pl are most closely related. The Pk has been found in a wild plum (Prunus domestica) in a new region of Russia indicating widespread dissemination of the PPV-W strain in the European part of the former USSR.

Molecular Analysis of a Plum pox virus W Isolate in Plum Germplasm Hand Carried into the USA from the Ukraine Shows a Close Relationship to a Latvian Isolate

Four of 19 Prunus germplasm accessions hand carried from the Ukraine into the United States without authorization were found to be infected with Plum pox virus (PPV). Of the three isolates characterized, isolates UKR 44189 and UKR 44191 were confirmed to be isolates of PPV strain W, and UKR 44188 was confirmed to be an isolate of PPV strain D. UKR 44189 and UKR 44191 are very closely related to the PPV strain W isolate LV-145bt (HQ670748) from Latvia. Nucleotide and amino acid sequence identities between these three isolates were greater than 99%. This indicates that the isolates are very closely related and likely originated from a common source. The high genetic diversity among PPV-W strain isolates allowed the identification of potential recombination events between PPV isolates. It appears also that GF 305 peach and Prunus tomentosa are not hosts for the PPV isolate UKR 44189.

Sharka: the past, the present and the future

Members the Potyviridae family belong to a group of plant viruses that are causing devastating plant diseases with a significant impact on agronomy and economics. Plum pox virus (PPV), as a causative agent of sharka disease, is widely discussed. The understanding of the molecular biology of potyviruses including PPV and the function of individual proteins as products of genome expression are quite necessary for the proposal the new antiviral strategies. This review brings to view the members of Potyviridae family with respect to plum pox virus. The genome of potyviruses is discussed with respect to protein products of its expression and their function. Plum pox virus distribution, genome organization, transmission and biochemical changes in infected plants are introduced. In addition, techniques used in PPV detection are accentuated and discussed, especially with respect to new modern techniques of nucleic acids isolation, based on the nanotechnological approach. Finally, perspectives on the future of possibilities for nanotechnology application in PPV determination/identification are outlined.

Occurrence and Genetic Diversity of Winona-Like Plum pox virus Isolates in Russia

In studying the distribution and genetic diversity of Plum pox virus (PPV) in Russia, over a dozen new PPV isolates belonging to the strain Winona (PPV-W) were identified by immunocapture reverse-transcription polymerase chain reaction with the PPV-W-specific primers 3174-SP-F3/3174-SP-R1. Isolates were detected in two geographically distant regions of European Russia (Northern Caucasus and Moscow regions) in naturally infected plum (Prunus domestica), blackthorn (P. spinosa), Canadian plum (P. nigra), and downy cherry (P. tomentosa). The new PPV-W isolates were shown to be serologically related but not identical by triple-antibody sandwich enzyme-linked immunosorbent assay and Western blotting analysis using the monoclonal antibody (MAb) 5B-IVIA and MAbs specific to the N-terminal epitopes of PPV-W isolate 3174. Analysis of nucleotide and deduced amino acid sequences of the (C-ter)NIb-(N-ter)CP genome region indicate great genetic diversity among isolates, with phylogenetic analysis revealing seven clades. Isolates P1 and P3 found in plum in the south of Russia clustered closely with the putative ancestral PPV-W isolate LV-145bt from Latvia, while isolate 1410-7 found in P. nigra in Moscow appears to be closely related to the Canadian isolate W3174. The data obtained indicate wide dissemination of PPV-W isolate in stone fruit in the European part of the former USSR.

Molecular, ultrastructural, and biological characterization of Pennsylvania isolates of Plum pox virus

Plum pox virus (PPV) was identified in Pennsylvania in 1999. The outbreak was limited to a four-county region in southern Pennsylvania. Initial serological and molecular characterization indicated that the isolates in Pennsylvania belong to the D strain of PPV. The Pennsylvania isolates were characterized by sequence analysis, electron microscopy, host range, and vector transmission to determine how these isolates related to their previously studied European counterparts. Genetically, Pennsylvania (PPV-Penn) isolates were more closely related to each other than to any other PPV-D strains, and isolates from the United States, Canada, and Chile were more closely related to each other than to European isolates. The PPV-Penn isolates exist as two clades, suggesting the possibility of multiple introductions. Electron microscopy analysis of PPV-Penn isolates, including cytopathological studies, indicated that the virions were similar to other Potyvirus spp. PPV-Penn isolates had a herbaceous host range similar to that of European D isolates. There were distinct differences in the transmission efficiencies of the two PPV-Penn isolates using Myzus persicae and Aphis spiraecola as vectors; however, both PPV-Penn isolates were transmitted by M. persicae more efficiently than a European D isolate but less efficiently than a European M isolate.

Analysis of the complete genome of peach chlorotic mottle virus: identification of non-AUG start codons, in vitro coat protein expression, and elucidation of serological cross-reactions

The entire genome of peach chlorotic mottle virus (PCMV), originally identified as Prunus persica cv. Agua virus (4N6), was sequenced and analysed. PCMV cross-reacts with antisera to diverse viruses, such as plum pox virus (PPV), genus Potyvirus, family Potyviridae; and apple stem pitting virus (ASPV), genus Foveavirus, family Flexiviridae. The PCMV genome consists of 9005 nucleotides (nts), excluding a poly(A) tail at the 3' end of the genome. Five open reading frames (ORFs) were identified with four untranslated regions (UTR) including a 5', a 3', and two intergenic UTRs. The genome organisation of PCMV is similar to that of ASPV and the two genomes share a nucleotide (nt) sequence identity of 58%. PCMV ORF1 encodes the replication-associated protein complex (Mr 241,503), ORF2-ORF4 code for the triple gene block proteins (TGBp; Mr 24,802, 12,370, and 7320, respectively), and ORF5 encodes the coat protein (CP) (Mr 42,505). Two non-AUG start codons participate in the initiation of translation: 35AUC and 7676AUA initiate translation of ORF1 and ORF5. In vitro expression with subsequent Western blot analysis confirmed ORF5 as the CP-encoding gene and confirmed that the codon AUA is able to initiate translation of the CP. Expression of a truncated CP fragment (Mr 39, 689) was demonstrated, and both proteins are expressed in vivo, since both were observed in Western blot analysis of PCMV-infected peach and Nicotiana occidentalis. The expressed proteins cross-reacted with an antiserum against ASPV. The amino acid sequences of the CPs of PCMV and ASPV CP share only 37% identity, but there are 11 shared peptides 4-8 aa residues long. These may constitute linear epitopes responsible for ASPV antiserum cross reactions. No significant common linear epitopes were associated with PPV. Extensive phylogenetic analysis indicates that PCMV is closely related to ASPV and is a new and distinct member of the genus Foveavirus.

Prunus Host Range of Plum pox virus (PPV) in the United States by Aphid and Graft Inoculation

Plum pox (Sharka) is a serious virus disease of stone fruits caused by the Plum pox virus (PPV). To determine which species could function as potential hosts and virus reservoirs, we used aphid transmission and bud or chip grafting to evaluate the susceptibility of commercial, ornamental, and wild Prunus species to isolates of PPV found in Pennsylvania, USA. Following inoculation, test trees were observed for symptoms, analyzed by enzyme-linked immunosorbent assay (ELISA) and polymerase chain reaction (PCR), back-assayed to healthy peach, and followed through at least four cold-induced dormancy (CID) cycles over 4 years. Thirty-one of 33 Prunus species and cultivars were systemically infected following aphid transmission. Systemic infection could not be detected in P. cerasus (sour cherry) and P. × 'Snofozam' (Snow Fountains) despite repeated aphid inoculation attempts. Following grafting of PPV-infected budwood, all 40 species and varieties became infected, although species differed in their susceptibility. Within most species, some individual plants remained PPV negative throughout the study despite repeated inoculations. Infection in some species could be detected only through quantitative reverse transcription (RT)-PCR. Most species displayed clear symptoms, were highly positive by ELISA and RT-PCR, and could be back-inoculated into peach seedlings following CID. Our results indicate that a wide range of native and ornamental Prunus species are susceptible to U.S. isolates of PPV-D.

Use of reverse transcription loop-mediated isothermal amplification for the detection of Plum pox virus

A one step, accelerated reverse transcription loop-mediated isothermal amplification (RT-LAMP) procedure was developed for the detection of Plum pox virus (PPV). The six primers required for accelerated RT-LAMP were designed using a conserved region in the C-terminus of the coat protein coding region of PPV. RT-LAMP was used to detect isolates of five strains of PPV including the strains D, M, EA, C, and W. The virus was detected reliably in both infected herbaceous and woody hosts. RT-LAMP was compared to real-time RT-PCR with SYBR Green I and melting curve analysis, using serial dilutions of total RNA extracts. Similar sensitivities were observed, except that real-time RT-PCR was more consistent at lower template concentrations. The purity of the FIP and BIP primers affected the efficiency of the reaction, and incubation time and template concentration affected the ladder-like pattern observed after agarose gel electrophoresis. Although PPV could be detected after 30min of incubation at 63 degrees C, a longer incubation time was required for lower concentrations of the target. RT-LAMP is a very sensitive, low cost diagnostic tool that should be of value in more accurate determination of the distribution of PPV. This should assist in preventing further spread of this devastating virus.

Real-time RT-PCR and SYBR Green I melting curve analysis for the identification of Plum pox virus strains C, EA, and W: Effect of amplicon size, melt rate, and dye translocation

Real-time RT-PCR and SYBR green I melt curve analysis of a 74 bp amplicon enabled identification of Plum pox virus strains C, EA, and W, with distinct T(m)'s associated with each strain. This test is a useful supplement to a real-time RT-PCR test described earlier that was used to distinguish PPV strains D and M. A longer fragment of 155 bp was not effective for strain identification. A simplified one-tube protocol, with dithiothreitol eliminated from the reaction, showed similar sensitivity when compared to a two-tube protocol. For melt curve analysis, a slower melt rate of 0.1 degrees C/s, compared to 0.4 degrees C/s, was effective for detecting weak amplicons, and improved resolution of the T(m) of amplicons amplified simultaneously. SYBR green I was useful for duplex melt curve analysis. In repeated melt run treatments (total of 14) of a single sample containing co-amplified targets, complete translocation of SYBR green I was observed, going from a 74 bp fragment to a 114 bp fragment. The duration of the melt run may be a critical factor affecting SYBR green I binding and translocation, and its manipulation may facilitate improved resolution and simultaneous detection of multiple targets. This phenomenon may explain inconsistent SYBR green I fluorescence patterns associated with melt curve analysis of some amplicon complexes.

Molecular Characterization, Phylogenetic Relationships, and Specific Detection of Peach mosaic virus

ABSTRACT Peach mosaic virus (PcMV) and Cherry mottle leaf virus (CMLV) are serologically related viruses that cause distinct diseases, have a different host range, and are vectored by different eriophyid mites. Sequence analysis of the genome of PcMV indicates that it is closely related genetically to CMLV but distinct, with similar genome organization and a member of the genus Trichovirus. The genome of PcMV consists of 7,988 nucleotides, excluding a poly(A) tail at the 3' end of the genome. Four putative open reading frames (ORF1 to 4) were identified coding for proteins of 216.3, 47.2, 21.7, and 15.7 kDa, respectively. Also, three noncoding regions were identified, including an intergenic region separating ORF3 and ORF4. The complete nucleotide sequence of PcMV shares 73% identity with CMLV. The CP amino acid sequence identity between isolates of PcMV ranged from 97 to 99% versus 83% identity when compared with the CP of CMLV. In vitro expression and subsequent western blot analysis confirmed ORF3 as encoding the CP gene of PcMV. Phylogenetic analysis supports classification of PcMV and CMLV as members of the genus Trichovirus. They are unique members of this genus with an extra ORF (ORF4). PcMV ORF4 appears to code for a putative nucleic acid-binding (NB) protein which has identity with the NB protein of CMLV and members of the genera Allexivirus, Carlavirus, and Vitivirus. PcMV and CMLV appear to be the products of recombination between members of the genus Trichovirus and a virus group containing the putative NB protein. Alternatively, PcMV and CMLV may represent the intact genome, with a deletion event producing members that lack ORF4. A reverse transcription-polymerase chain reaction procedure was developed for reliable and specific detection of PcMV. This will be an asset for stone fruit virus certification.

The complete genome sequence of an El Amar isolate of plum pox virus (PPV) and its phylogenetic relationship to other PPV strains

The genomic sequence of an El Amar isolate of plum pox virus (PPV) from Egypt was determined by sequencing overlapping cDNA fragments. This is the first complete sequence of a member of the El Amar (EA) strain of PPV. The genome consists of 9791 nt, excluding a poly(A) tail at the 3' terminus. The complete nt sequence of PPV EA is 79-80%, 80%, 77%, and 77% homologous with isolates of strains D/M, Rec (BOR3), C, and W, respectively. The polyprotein identity ranged from 87-91%. Phylogenetic analysis using the complete genome sequence of PPV EA confirmed its strain status. No significant recombination signals were identified using PhylPro and SimPlot scans of the PPV EA sequence, however an interesting recombination signal was identified in the P1/HC-Pro region of PPV W3174.

Nucleotide sequence analysis of Plum pox virus isolate W3174: evidence of a new strain

The nucleotide sequence of Plum pox virus (PPV) isolate W3174 was determined. The virus genome consists of 9788 nucleotides (nt), excluding the poly(A) tail at the 3'-terminus, with 5'- and 3'-untranslated regions (UTRs) of 146 and 219 nt, respectively. The deduced polyprotein consists of 3141 amino acid (aa) residues, with the coat protein region consisting of 993 nt (331 aa). In comparisons with PPV-D, -M, -EA and -C isolates, nucleotide identity levels ranged from 79 to 80% for the entire genome and from 78 to 79%, 78 to 81%, and 92 to 95% for the NIb, CP, and 3'-UTR regions, respectively. The majority of nucleotide substitutions in the NIb region of W3174 are silent, while substitutions in the CP region are not silent, giving aa identities of 89-91% and 79-81%, respectively. The HC-Pro region contains the KITC and PTK motifs, and the DAG motif is located at positions 12-14 of the deduced CP aa sequence, all associated with aphid transmission. Phylogenetic analysis based on the complete genome sequence, the NIb, CP, and 3'-UTR region were performed. PPV-W3174 consistently formed a distinct clade or group, when compared to members of all four recognized strains of PPV, indicating that it is genetically distinct. These results are consistent with serological and nucleic acid-based strain typing data and justify recognition of this isolate as representative of a new strain identified as PPV-W.

Partial sequence analysis of an atypical Turkish isolate provides further information on the evolutionary history of Plum pox virus (PPV)

A variety of techniques, such as typing with subgroup-specific monoclonal antibodies, restriction length polymorphism (RFLP) analysis or subgroup-specific RT-PCR are available for the discrimination of Plum pox virus (PPV) isolates. However, the existence of PPV isolates showing abnormal typing properties has been observed in the past [Candresse, T., Cambra, M., Dallot, S., Lanneau, M., Asensio, M., Gorris, M.T., Revers, F., Macquaire, G., Olmos, A., Boscia, D., Quiot J.B., Dunez, J., 1998. Comparison of monoclonal antibodies and polymerase chain reaction assays for the typing of isolates belonging to the D and M serotypes of Plum pox potyvirus. Phytopathology 88, 198-204.]. In an effort to understand the molecular mechanisms underlying such anomalous serological and molecular typing characteristics, partial 3' (1449 nt) and 5' (3706 nt) sequences have been determined for an atypical Turkish PPV isolate (Abricotier Turquie or Ab-Tk). The results obtained indicate that its unusual typing behaviour is caused by point mutations affecting key restriction sites and epitopes and confirm that this isolate represents a divergent member of the PPV-M subgroup. In addition, analysis of the partial Ab-Tk genomic sequences demonstrated that the 5' region of the genome of this isolate has a mosaic structure resulting from recombination event(s), shedding new light on the evolutionary history of Plum pox virus.

Analysis of recombinant Plum pox virus (PPV) isolates from Serbia confirms genetic homogeneity and supports a regional origin for the PPV-Rec subgroup

The recent observation of the frequent occurrence of natural recombinant Plum pox virus (PPV) isolates has led to the identification of a distinct PPV subgroup, named PPV-Rec. The diversity, origin and geographical spread of the recombinant PPV isolates belonging to this subgroup remain, however, relatively poorly known. In an effort to further our understanding of these isolates, eight PPV isolates from Serbia, the country from which the first such recombinant (PPV-o6) originated, were characterized. Depending on the genomic region targeted by different typing assays, seven of the eight isolates tested presented discrepancies in their typing behavior. Sequence analysis of the (Cter)NIb-(Nter)CP region confirmed the recombinant nature of these seven isolates which all presented an identical recombination breakpoint identical to previously characterized PPV-Rec isolates. Biological indexing and immunoblot analysis provided indications that asymptomatic infection of the GF305 peach indicator and migration of the coat protein as a double-band in immunoblots may represent conserved and discriminating properties of PPV-Rec isolates. The genetic diversity of PPV-Rec isolates from former Yugoslavia (Serbia, Bosnia and Herzegovina) was estimated to be twice as large as that of the PPV-Rec isolates obtained from all other countries to date (Albania, Bulgaria, Czech republic, Germany, Hungary and Slovakia). These last results are consistent with the hypothesis that former Yugoslavia is the center of dispersion of PPV-Rec. Taken together, the results presented here provide further evidence for the wide distribution and temporal genetic stability of these natural PPV recombinant isolates and provide for the first time a possible scenario for their dispersion throughout central and eastern Europe.

Detection and differentiation of Plum pox virus using real-time multiplex PCR with SYBR Green and melting curve analysis: a rapid method for strain typing

A real-time multiplex PCR procedure with melting curve analysis, using the green fluorescence dye SYBR Green I, was developed for rapid and reliable identification of Plum pox virus (PPV) isolates of strains D and M. Members of the different strains were identified by their distinctive melting temperatures (T(m)s); 84.3-84.43 degrees C for D isolates, and 85.34-86.11 degrees C for M isolates. The associated amplicon sizes were 114 and 380 bp, respectively. The procedure was used for detection and identification of PPV in both herbaceous and woody hosts. The Tm for members of a particular strain was very similar, with a host effect that did not hinder strain identification. Universal primers included in the study detected all isolates of PPV tested, amplifying a 74 bp fragment. The Tm of this fragment varied from 80.12 to 81.52 degrees C and may have supplementary value for PPV identification. SYBR Green-based detection was compared to detection using a hybridization LUX fluorogenic primer. Better resolution of the melting peaks was observed with SYBR Green I, than with the LUX primers, hence strain identification with SYBR Green I was more reliable. This is a simple approach to PPV strain identification with the relatively inexpensive dye SYBR Green I, and eliminates any need for electrophoretic analysis of amplicons or RFLP patterns using ethidium bromide.

Detection and Partial Molecular Characterization of Two Plum pox virus Isolates from Plum and Wild Apricot in Southeast Kazakhstan

Plum pox virus (PPV) was detected in wild apricot and cultivated plum maintained in a germ plasm collection in Kazakhstan. Both isolates were typed as D strain, with no evidence of recombination. The virus was detected by triple-antibody sandwich enzyme-linked immunosorbent assay (ELISA) utilizing the universal PPV-specific monoclonal antibody (MAb) 5B as the secondary antibody, and by reverse-transcription polymerase chain reaction (RT-PCR) assay using primers that amplified a 243-bp fragment in the C-terminus of the coat protein (CP) coding region. Immunocapture (IC) RT-PCR was used to detect PPV in nine wild apricot accessions, including eight ELISA-negative and one ELISA-positive. The plum and apricot isolates reacted positively in Western blot assay with the universal MAb 5B, and negatively with the strain-M-specific MAb-AL. Restriction fragment length polymorphism analysis applied to the amplified 243-bp fragment showed that restriction sites for AluI and RsaI were present in the were present in the plum and apricot samples. An amplified 836-bp cDNA fragment derived from the P3-6K₁ coding region of both isolates had restriction profiles typical for strain D. Nucleotide identities of 99 to 100% were observed for the 243-bp fragments of the Kazakhstan isolates when compared with the corresponding regions of strain D, and 94 to 95% identity with strain M. Nucleotide sequence analysis of the entire CP coding region of the plum and apricotisolates resulted in the identification of a unique deletion of six nucleotides (two deduced proline amino acid residues) in the N-terminal region in the plum isolate. This is the first deletion of this nature observed among PPV isolates. The DAG motif was present in both isolates. Several nucleotide substitutions in the CP coding region were common to the plum and apricot isolates and appear to be unique to the Kazakstan isolates. This suggests a close relationship between the isolates.

Geographically and temporally distant natural recombinant isolates of Plum pox virus (PPV) are genetically very similar and form a unique PPV subgroup

Natural recombinant Plum pox virus (PPV) isolates were detected in Albania, Bulgaria, Czech Republic, Germany, Hungary and Slovakia. Despite different geographical origins and dates of isolation, all the recombinant isolates were closely related at the molecular level and shared the same recombination breakpoint as well as a typical signature in their N-terminal coat protein sequence, suggesting a common origin. Biological assays with four recombinant isolates demonstrated their capacity to be aphid-transmitted to various Prunus hosts. One of these isolates had a threonine-to-isoleucine mutation in the conserved PTK motif of its HC-Pro and showed a drastically decreased, although not abolished, aphid transmissibility. The complete genome sequence of one of the recombinant isolates, BOR-3, was determined, as well as some partial sequences in the HC-Pro and P3 genes for additional natural recombinant isolates. Analysis of the phylogenetic relationships between the recombinant isolates and other sequenced PPV isolates confirmed that the recombinant isolates form a phylogenetically homogeneous lineage. In addition, this analysis revealed an ancient recombination event between the PPV-D and M subgroups, with a recombination breakpoint located in the P3 gene. Taken together, these results indicate that recombinant isolates represent an evolutionarily successful, homogeneous group of isolates with a common history and unique founding recombination event. The name PPV-Rec is proposed for this coherent ensemble of isolates.