New Disease Reports (2012) 26, 7. [http://dx.doi.org/10.5197/j.2044-0588.2012.026.007]
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First report of Tomato apical stunt viroid in Solanum jasminoides in Slovenia

M. Viršček Marn* and I. Mavrič Pleško

*mojcavm@kis.si

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Received: 17 Apr 2012; Published: 15 Sep 2012

Keywords: pospiviroids, Potato spindle tuber viroid, Citrus exocortis viroid

A survey of Potato spindle tuber viroid (PSTVd) in ornamental host plants was initiated in Slovenia in December 2006 after a PSTVd infection was confirmed in an ornamental plant Brugmansia cordata imported from the Netherlands. By the end of 2010, PSTVd had also been detected in Solanum jasminoides, S. rantonnetii, S. muricatum and Petunia spp. Furthermore, after the detection of Tomato chlorotic dwarf viroid (TCDVd) in Petunia sp. (Viršček Marn & Mavrič Pleško, 2010) and Citrus exocortis viroid (CEVd) in S. jasminoides (Viršček Marn & Mavrič Pleško, 2011) in 2010, an assessment of the risk of pospiviroids for Slovenia was performed at the beginning of 2011. The results of pest risk analysis showed that pospiviroids pose a serious threat to important agricultural plants. Symptomless pospiviroid-infected ornamental plants were proposed to be a probable source of infection for agricultural crops. Sampling of all pospiviroid hosts and destruction of all pospiviroid-infected lots was therefore implemented in Slovenia in 2011.

In 2011, 14 samples were taken from symptomless S. jasminoides plants in greenhouses and retail trade and were tested by one-step RT-PCR using semi-universal pospiviroid primers Pospi1-RE/FW and Vid-RE/FW (cited in Verhoeven et al., 2008). With three samples, PCR products were obtained with both primer pairs. They were all directly sequenced (Macrogen, The Netherlands). Sequence analysis of PCR products obtained with both primer pairs from two samples confirmed infection with PSTVd. Sequences of amplification products obtained with the Vid-RE/FW primer pair from the third sample showed the highest similarity with PSTVd whereas the sequences of the amplicon obtained with Pospi1-RE/FW primers suggested the presence of Tomato apical stunt viroid (TASVd). A second total RNA extraction was made; both extracted RNAs were further used in RT-PCRs using primer pairs of Shamloul et al. (1997) and of Di Serio (2007) for detection of PSTVd, and primer pairs of Elleuch et al. (2003) and Verhoeven et al. (2008) for detection of TASVd and CEVd. Sequence analysis confirmed the presence of PSTVd and TASVd. PSTVd and TASVd sequences of this doubly infected sample were deposited in the GenBank (Accession Nos. JN559763 and JN543957, respectively). 

Successful amplification with only Pospi1-RE/FW was obtained with 10 samples. These amplification products were also directly sequenced and sequence analysis revealed the presence of CEVd in three samples and the presence of TASVd in seven samples. To obtain full viroid sequences further analyses were made using primer pairs of Elleuch et al. (2003) and Verhoeven et al. (2008). These sequences have also been deposited in GenBank (JQ083645 to JQ083647 for CEVd and JN872141 to JN872144 and JQ904911 for TASVd). This is the first record of TASVd in Slovenia. All Slovene TASVd sequences had 370 nt and were identical to each other at 366 positions. They shared 98.9 to 100% identity among themselves and 97.5 to 100% identity with other TASVd sequences from S. jasminoides. The variability of sequences detected in S. jasminoides in Slovenia and worldwide is rather small. This data suggest a possible common origin of TASVd infection of S. jasminoides. Higher variability was observed between TASVd sequences from S. jasminoides and from tomato. The most distant sequences shared only 92.0% identity. 


References

  1. Di Serio F, 2007. Identification and characterization of Potato spindle tuber viroid infecting Solanum jasminoides and S. rantonnetii in Italy. Journal of Plant Pathology 89, 297-300.
  2. Elleuch A, Marrakchi M, Lévesque D, Bessais N, Perreault JP, Fakhfakh H, 2003. Molecular variability of Citrus exocortis viroid in a single infected citrus tree. Plant Protection Science 39, 139-145.
  3. Shamloul AM, Hadidi A, Zhu SF, Singh RP, Sagredo B, 1997. Sensitive detection of potato spindle tuber viroid using RT-PCR and identification of a viroid variant naturally infecting pepino plants. Canadian Journal of Plant Pathology 19, 89–96. [http://dx.doi.org/10.1080/07060669709500580]
  4. Verhoeven JThJ, Jansen CCC, Roenhorst  JW, 2008. First report of Solanum jasminoides infected by Citrus exocortis viroid in Germany and The Netherlands and Tomato apical stunt viroid in Belgium and Germany. Plant Disease 92, 973. [http://dx.doi.org/10.1094/PDIS-92-6-0973A]
  5. Viršček Marn M, Mavrič Pleško I, 2010. First report of Tomato chlorotic dwarf viroid in Petunia spp. in Slovenia. Plant Disease 94, 1171. [http://dx.doi.org/10.1094/PDIS-94-9-1171B ]
  6. Viršček Marn M, Mavrič Pleško I, 2011. Detection of Citrus exocortis viroid in Solanum jasminoides in Slovenia. Journal of Plant Pathology 93, S4.79. [http://dx.doi.org/10.4454/jpp.v93i4.2392]

To cite this report: Viršček Marn M, Mavrič Pleško I, 2012. First report of Tomato apical stunt viroid in Solanum jasminoides in Slovenia. New Disease Reports 26, 7. [http://dx.doi.org/10.5197/j.2044-0588.2012.026.007]

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