New Disease Reports (2015) 32, 1. [http://dx.doi.org/10.5197/j.2044-0588.2015.032.001]
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First report of 'Candidatus Liberibacter solanacearum' in Jerusalem cherry (Solanum pseudocapsicum) and thorn-apple (Datura stramonium) in New Zealand

J. Vereijssen 1,2*, N.M. Taylor 1,3, A.M. Barnes 1,2, S.E. Thompson 1,2, D.P. Logan 1,4, R.C. Butler 2, A.L. Yen 1,5 and K.J. Finlay 1,5

*Jessica.Dohmen-Vereijssen@plantandfood.co.nz

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Received: 05 May 2015; Published: 12 Jul 2015

Keywords: Bactericera cockerelli

Tomato potato psyllid (TPP), Bactericera cockerelli, is a vector of the bacterium 'Candidatus Liberibacter solanacearum' (CLso). The pathogen and insect severely impact solanaceous crops in the USA, Central America and New Zealand (Haapalainen, 2014; Liefting et al., 2009). As weeds infected with CLso could be reservoirs of the pathogen in the absence of crops (Murphy et al., 2014), weeds surrounding tomato crops in Hawke’s Bay (North Island) were monitored every three months for presence of TPP between September 2013 and October 2014. When all life stages of TPP were found regularly on a weed, insect and plant samples were collected to test for CLso. 

All life stages of TPP were observed on two weed species, Solanum pseudocapsicum and Datura stramonium. S. pseudocapsicum showed yellowing/chlorosis (Fig. 1), but D. stramonium was symptomless. These species were tested for the presence of CLso by extracting two independent total DNA samples from the plants collected using CTAB (Beard et al., 2013). DNA was extracted from: (i) below-ground stem tissue samples of six S. pseudocapsicum plants, field collected on 6 June and 3 October 2014 in Maraekakaho; and (ii) main stem (three plants) and below-ground stem tissue (one plant) of D. stramonium plants, field collected on 27 May 2014 in Meeanee. A single-tube semi-nested SYBR Green real-time PCR (qPCR) was performed with primers LsoF-Lso16SF-Lso16SRI (Beard et al., 2013). Total DNA was also extracted from B. cockerelli life stages on these plants (Beard & Scott, 2013). Infected and uninfected non-related plant material or TPP were used as positive and negative controls. CLso was detected in two of the ten plant samples: one D. stramonium at low titre and one S. pseudocapsicum (3 October) at high titre (Fig. 2). Low titre is defined as cycle threshold (Ct) >35 (unable to accurately quantify CLso molecules present) but the SYBR Green melting curve is identical to the positive control (Fig. 2). TPP collected from these two plants also tested positive for CLso: three out of five adults from S. pseudocapsicum and two of five late instar nymphs. One of six adult TPP tested positive for CLso. These insects came from a three square metre patch of D. stramonium that included the plant that was found CLso-positive.

To our knowledge, this is the first report of CLso infecting weed species in New Zealand. The D. stramonium sample that tested positive for CLso was collected in autumn, while S. pseudocapsicum was collected in spring. In both situations, there was no crop present at the time of collection. Although the incidence of weeds infected with CLso in the environment may be low, they may be a potential reservoir for the pathogen and the vector in the absence of a suitable crop host, providing a potential inoculum source for infection of subsequent crops.

Figure1+
Figure 1: Solanum pseudocapsicum, infested with Bactericera cockerelli which tested positive for the presence of 'Candidatus Liberibacter solanacearum', showing chlorosis of the leaves.
Figure 1: Solanum pseudocapsicum, infested with Bactericera cockerelli which tested positive for the presence of 'Candidatus Liberibacter solanacearum', showing chlorosis of the leaves.
Figure2+
Figure 2: qPCR meltcurve plot for two independent DNA extractions from the Solanum pseudocapsicum and Datura stramonium plant samples. Ct: cycle threshold; U: undetermined.
Figure 2: qPCR meltcurve plot for two independent DNA extractions from the Solanum pseudocapsicum and Datura stramonium plant samples. Ct: cycle threshold; U: undetermined.

Acknowledgements

The authors would like to acknowledge the support of the Australian Government’s Cooperative Research Centres Program.


References

  1. Beard SS, Pitman AR, Kraberger S, Scott IAW, 2013. SYBR Green real-time quantitative PCR for the specific detection and quantification of 'Candidatus Liberibacter solanacearum' in field samples from New Zealand. European Journal of Plant Pathology 136, 203-215. [http://dx.doi.org/10.1007/s10658-012-0156-5]
  2. Beard SS, Scott IAW, 2013. A rapid method for the detection and quantification of the vector-borne bacterium 'Candidatus Liberibacter solanacearum' in the tomato potato psyllid, Bactericera cockerelli. Entomologia Experimentalis et Applicata 147, 196-200. [http://dx.doi.org/10.1111/eea.12056]
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To cite this report: Vereijssen J, Taylor NM, Barnes AM, Thompson SE, Logan DP, Butler RC, Yen AL, Finlay KJ, 2015. First report of 'Candidatus Liberibacter solanacearum' in Jerusalem cherry (Solanum pseudocapsicum) and thorn-apple (Datura stramonium) in New Zealand. New Disease Reports 32, 1. [http://dx.doi.org/10.5197/j.2044-0588.2015.032.001]

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