New Disease Reports (2019) 39, 19. [http://dx.doi.org/10.5197/j.2044-0588.2019.039.019]
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First report of 'Candidatus Phytoplasma rubi' on blackberry in Belgium

K. De Jonghe* and T. Goedefroit

*kris.dejonghe@ilvo.vlaanderen.be

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Received: 22 Feb 2019; Published: 28 May 2019

Keywords: ‘elm yellows phytoplasma’, Rubus fruticosus, ‘Rubus stunt phytoplasma’, 16SrV phytoplasma

In May 2018 stunted blackberry plants were observed on a small-scale organic farm producing several small fruit types in West Flanders, Belgium. Besides severe stunting, leaf yellowing and distortions could also be observed (Figs. 1-2). Only Rubus fruticosus plants of the cultivar Obsidian showed symptoms but disease incidence was estimated to be almost 100%, of which almost half the plants were stunted. Other cultivars did not seem affected.

Seven symptom-bearing plants, of which four had severe stunting, and three only leaf symptoms, were sampled and tested. Additionally, three symptomless plants from neighbouring rows and belonging to different cultivars, were tested. All samples consisted of leaves and roots, and tests were conducted on a pooled leaf/root sample. Total genomic DNA was extracted by a CTAB protocol. The 16S rRNA gene was partially amplified using the phytoplasma universal primer pair P1/P7 (Deng & Hiruki, 1991; Schneider et al., 1995) followed by a nested PCR with R16F2/R2 primers (Lee et al., 1993) as a diagnostic test, and P1/Tint primers (Smart et al., 1996) on positive samples for sequencing. All of the diseased plants tested positive for phytoplasma in nested PCR tests. Additionally, specific phytoplasma group V primers targeting the tuf (FDTUF-F1/R1 & FDTUF-F2/R2; Malembic-Maher et al., 2011), and secY (primer sets FD9f2L/FD9r & FD9f3L/FD9r2L; Arnaud et al., 2007) genes were used in nested PCRs and  yielded fragments of 998 and 1174 bp respectively.

The obtained 16SrRNA (P1/Tint), tuf and secY fragments were gel purified (SmartPure, Eurogentec), and sequenced directly (Genewiz, Leipzig, Germany). BLAST analysis of the 16SrRNA sequence, revealed the highest identity (99.85%) with a 'Rubus stunt phytoplasma' strain from blackberry (R. fruticosus) in Italy (isolate RuS400; GenBank Accession No. AY197649). Partial sequence of the 16S ribosomal RNA (1607 bp), and tuf (835 bp) and secY  (1053 bp) genes were submitted to GenBank (MH801133, MH809672 and MH809673, respectively). Phylogenetic analysis was undertaken on all three fragments, and the phytoplasma was identified as 'Candidatus Phytoplasma rubi', 'elm yellows' group 16SrV-E (Figs. 3-5). To our knowledge, this is the first report of 'Ca. P. rubi' on blackberry in Belgium.  An additional nationwide survey is needed to assess the phytopathological impact of this outbreak. Although a growing number of reports indicate the increased importance of Rubus stunt, associated with 'Ca. P. rubi', unlike the related 'Ca. P. ulmi', associated with elm trees, no regulatory actions are currently taken against this pathogen.

Figure1+
Figure 1: Plants of Rubus fruticosus cv. Obsidian in West Flanders, Belgium showing severe stunting.
Figure 1: Plants of Rubus fruticosus cv. Obsidian in West Flanders, Belgium showing severe stunting.
Figure2+
Figure 2: Rubus fruticosus cv. Obsidian in West Flanders, Belgium showing leaf malformation and yellowing.
Figure 2: Rubus fruticosus cv. Obsidian in West Flanders, Belgium showing leaf malformation and yellowing.
Figure3+
Figure 3: Phylogenetic tree of partial 16S rRNA gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession number shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of base substitutions per site.
Figure 3: Phylogenetic tree of partial 16S rRNA gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession number shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of base substitutions per site.
Figure4+
Figure 4: Phylogenetic tree of partial secY gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession numbers shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of amino acid substitutions per site.
Figure 4: Phylogenetic tree of partial secY gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession numbers shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of amino acid substitutions per site.
Figure5+
Figure 5: Phylogenetic tree of partial tuf gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession numbers shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of amino acid substitutions per site.
Figure 5: Phylogenetic tree of partial tuf gene sequences from the 'Ca. P rubi'-related phytoplasma strain identified in this study (marked by a green dot) and phytoplasma type species (accession numbers shown before common name). Tree constructed by the neighbour-joining method. Bootstrap values (1000 replicates) shown next to the branches. Bar indicates evolutionary distances in units of the number of amino acid substitutions per site.

References

  1. Arnaud G, Malembic-Maher S, Salar P, Bonnet P, Maixner M, Marcone C, Boudon-Padieu E, Foissac F, 2007. Multilocus sequence typing confirms the close genetic interrelatedness of three distinct flavescence dorée phytoplasma strain clusters and group 16SrV phytoplasmas infecting grapevine and alder in Europe. Applied and Environmental Microbiology 73, 4001-4010. [http://dx.doi.org/10.1128/AEM.02323-06]
  2. Deng S, Hiruki C, 1991. Amplification of 16 S rRNA genes from culturable and nonculturable mollicutes. Journal of Microbiological Methods 14, 53-61. [http://dx.doi.org/10.1016/0167-7012(91)90007-D]
  3. Lee I-M, Hammond RW, Davis RE, Gundersen DE, 1993. Universal amplification and analysis of pathogen 16S rDNA for classification and identification of mycoplasmalike organisms. Phytopathology 83, 834-842. [http://dx.doi.org/10.1094/Phyto-83-834]
  4. Malembic-Maher S, Salar P, Filippin L, Carle P, Angelini E, Foissac X, 2011. Genetic diversity of European phytoplasmas of the 16SrV taxonomic group and proposal of 'Candidatus Phytoplasma rubi'. International Journal of Systematic and Evolutionary Microbiology , 2129-2134.  [http://dx.doi.org/10.1099/ijs.0.025411-0]
  5. Schneider B, Seemüller E, Smart CD, Kirkpatrick BC, 1995. Phylogenetic classification of plant pathogenic mycoplasma-like organisms or phytoplasmas. In: Razin S, Tully JG, eds. Molecular and Diagnostic Procedures in Mycoplasmology. New York, USA: Academic Press, 369-380.   [http://dx.doi.org/10.1016/B978-012583805-4/50040-6]
  6. Smart CD, Schneider B, Blomquist CL, Guerra LJ, Harrison NA, Ahrens U, Lorenz KH, Seemüller E, Kirkpatrick BC, 1996. Phytoplasma-specific PCR primers based on sequences of the 16S-23S rRNA spacer region. Applied and Environmental Microbiology 62, 2988-2993.

To cite this report: De Jonghe K, Goedefroit T, 2019. First report of 'Candidatus Phytoplasma rubi' on blackberry in Belgium. New Disease Reports 39, 19. [http://dx.doi.org/10.5197/j.2044-0588.2019.039.019]

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