PM 7/62 (2) ‘Candidatus Phytoplasma mali’, ‘Ca. P. pyri’ and ‘Ca. P. prunorum’

Specific scope

This Standard describes a diagnostic protocol for ‘Candidatus Phytoplasma mali’, ‘Ca. P. pyri’ and ‘Ca. P. prunorum’. This Standard should be used in conjunction with PM 7/76 Use of EPPO diagnostic protocols

Specific approval and amendment

Approved as PM 7/62 Candidatus Phytoplasma mali and PM 7/63 Ca. P. pyri in 2006. Revised in 2017‐02 as a single Standard as PM 7/62 (2) with the addition of ‘Ca. P. prunorum’.     

Increased plant tolerance against chrysanthemum yellows phytoplasma (‘Candidatus Phytoplasma asteris’) following double inoculation with Glomus mosseae BEG12 and Pseudomonas putida S1Pf1Rif

The aim of this work was to assess the effects of a combined inoculum of a rhizobacterium and an arbuscular mycorrhizal (AM) fungus on plant responses to phytoplasma infection, and on phytoplasma multiplication and viability in Chrysanthemum carinatum plants infected by chrysanthemum yellows phytoplasma (CY). Combined inoculation with Glomus mosseae BEG12 and Pseudomonas putida S1Pf1Rif resulted in some resistance to phytoplasma infection (about 30%), delayed symptom expression in nonresistant plants, improved growth of the aerial part of the infected plants (+68·1%), and altered root morphology (root tip number: +49·9%; branching degree: +82·8%). Combined inoculation with the two beneficial microorganisms did not alter CY multiplication and viability. In inoculated and infected plants, phytoplasma morphology was typical of senescent cells. A more active and efficient root system in double‐inoculated plants probably mediated the effects of the two rhizospheric microorganisms in the infected plants. The practical application of rhizospheric microorganisms for mitigating phytoplasma damage, following evaluation under field conditions, represents an additional tool for the integrated management of phytoplasmosis.     

Genetic and serological analyses of elongation factor EF‐Tu of paulownia witches’‐broom phytoplasma (16SrI‐D)

This study determined the tuf gene sequence of the phytoplasma specific to paulownia witches’‐broom from Nanyang, China (hereby designated PaWB‐Ny). The PaWB‐Ny tuf gene was 1185 nucleotides in length and confirmed that the phytoplasma belongs to subgroup 16SrI‐D of aster yellows. Three characteristic GTP‐binding protein motifs were identified based on the peptide deduced from the tuf gene sequence. Results suggested that the elongation factor EF‐Tu was localized in the cytoplasm and lacked hydrophobic transmembrane domains. Antibodies against PaWB‐Ny EF‐Tu were prepared by rabbit immunization with glutathione‐S‐transferase (GST)‐tagged EF‐Tu fusion protein expressed in Escherichia coli. EF‐Tu exhibited a molecular weight of ～43 kDa and was detected in PaWB‐infected paulownia plants by western blot analysis. Indirect enzyme‐linked immunosorbent assays (ELISA) and dot blotting analyses were performed with freezing and thawing treatments during antigen preparation. Dilution of extracts to an appropriate scale significantly reduced non‐specific reactions. The resultant PaWB EF‐Tu antibody reacted with antigens from plants infected with periwinkle virescence and chinaberry tree witches’‐broom phytoplasmas, but not those infected with jujube witches’‐broom or bishopwood witches’‐broom phytoplasma. The EF‐Tu was characteristically localized within the phytoplasmal cytoplasm of infected plant phloem tissues.     

Transmission of ‘Candidatus Phytoplasma pyri’ by naturally infected Cacopsylla pyri to peach,an approach to the epidemiology of peach yellow leaf roll (PYLR) in Spain

Peach orchards in the northeast of Spain were severely affected in 2012 by a previously unreported disease in this area. The symptoms included early reddening, leaf curling, decline, abnormal fruits, and in some cases death of the peach trees. All the infected peach samples were positive for ‘Candidatus Phytoplasma pyri’, but none were infected by the ‘Ca. Phytoplasma prunorum’. In this work, potential vectors able to transmit ‘Ca. Phytoplasma pyri’ from pear to peach and between peach trees were studied and their infective potential was analysed at different times of the year. Transmission trials of the phytoplasma with potential vectors to an artificial feeding medium for insects and to healthy peach trees were conducted. Additionally, isolated phytoplasmas were genetically characterized to determine which isolates were able to infect peach trees. Results showed that the only insect species captured inside peach plots that was a carrier of the ‘Ca. Phytoplasma pyri’ phytoplasma was Cacopsylla pyri. Other insect species captured and known to be phytoplasma transmitters were present in very low numbers, and were not infected with ‘Ca. Phytoplasma pyri’ phytoplasma. A total of 1928 individuals of C. pyri were captured in the peach orchards, of which around 49% were phytoplasma carriers. All the peach trees exposed to C. pyri in 2014, and 65% in 2015, were infected by ‘Ca. Phytoplasma pyri’ 1 year after exposure, showing that this species is able to transmit the phytoplasma to peach. Molecular characterization showed that some genotypes are preferentially determined in peach.     

Expression of phytoplasma‐induced witches’ broom disease symptoms in acid lime (Citrus aurantifolia) trees is affected by climatic conditions

Witches’ broom disease (WBD), caused by ‘Candidatus Phytoplasma aurantifolia’, is a serious disease of acid lime (Citrus aurantifolia) in Oman and the UAE. However, little is known about the distribution of phytoplasma and the expression of WBD symptoms in different geographical locations. A survey was carried out in 18 districts in Oman and the UAE covering 143 orchards and 5823 acid lime trees. ‘Candidatus Phytoplasma aurantifolia’ was detected in acid lime in all the 18 surveyed districts. However, the development of typical symptoms of WBD was only observed in 12 districts. Districts in which the phytoplasma was present but symptoms were not expressed were located either in desert areas or in areas characterized by semitropical conditions. Phylogenetic analysis of 16 phytoplasma isolates from trees developing WBD symptoms and six phytoplasma isolates from trees with no WBD symptoms showed that all isolates share an identical 16S rRNA sequence, belonging to subgroup II‐B. Quantitative PCR analysis showed that the concentration of phytoplasma is significantly higher (8800–801 000 copies) in leaves developing WBD symptoms compared to 2–268 copies in symptomless leaves from the same trees and 8–874 copies in acid lime trees from areas where disease symptoms were not expressed. The lack of expression of WBD symptoms under certain environmental conditions may suggest that symptom development and phytoplasma are affected by certain unfavourable environmental conditions. These findings could provide a basis for managing WBD through encouraging lime cultivation under climatic conditions less conducive to WBD symptom expression.     

Test performance study of isothermal amplification tests for the detection of Grapevine flavescence dorée phytoplasma and ‘Candidatus Phytoplasma solani’

This test performance study (TPS) was carried out on DNA samples from grapevine, clematis, fungi and bacteria to compare and validate loop‐mediated isothermal amplification (LAMP) tests for detection of Grapevine flavescence dorée phytoplasma and ‘Candidatus Phytoplasma solani’ (Grapevine Bois noir phytoplasma). Two LAMP tests, for Grapevine flavescence dorée phytoplasma and ‘Candidatus Phytoplasma solani’ (as developed by Kogov?ek and colleagues), with proven applicability for rapid laboratory or on‐site detection were included in this study. They were performed in 10 laboratories. In addition, the commercial Qualiplante/Hyris isothermal amplification test for Grapevine flavescence dorée phytoplasma was performed in three laboratories. The accuracy of the three tests was shown to be over 98%. Moreover, the high accuracy of these tests, which used different devices across different laboratories, confirmed their reproducibility.     

New natural host plants of ‘Candidatus Phytoplasma pini’ in Poland and the Czech Republic

The presence of phytoplasmas in seven coniferous plant species (Abies procera, Pinus banksiana, P. mugo, P. nigra, P. sylvestris, P. tabuliformis and Tsuga canadensis) was demonstrated using nested PCR with the primer pairs P1/P7 followed by R16F2n/R16R2. The phytoplasmas were detected in pine trees with witches’ broom symptoms growing in natural forest ecosystems and also in plants propagated from witches’ brooms. Identification of phytoplasmas was done using restriction fragment length polymorphism analysis (RFLP) of the 16S rDNA gene fragment with AluI, MseI and RsaI endonucleases. All samples showed RFLP patterns similar to the theoretical pattern of ‘Candidatus Phytoplasma pini’, based on the sequence of the reference isolate Pin127S. Nested PCR‐amplified products, obtained with primers R16F2n/R16R2, were sequenced. Comparison of the 16S rDNAs obtained revealed high (99·8–100%) nucleotide sequence identity between the phytoplasma isolates. The isolates were also closely related to four other phytoplasma isolates found in pine trees previously. Based on the results of RFLP and sequence analyses, the phytoplasma isolates tested were classified as members of the ‘Candidatus Phytoplasma pini’, group 16SrXXI.     

PM 9/25 (1) Bactericera cockerelli and ‘Candidatus Liberibacter solanacearum’

Specific scope

This Standard describes a national regulatory control system for Bactericera cockerelli and the bacterial pathogen ‘Candidatus Liberibacter solanacearum’ the cause of zebra chip disease in potato. The scope is as follows:

• Exclusion from the EPPO region of B. cockerelli an efficient vector of ‘Ca. L. solanacearum’ within solanaceous crops (e.g. potato, tomato)
• Eradication of incursions of B. cockerelli
• Exclusion from the EPPO region of ‘Ca. L. solanacearum’ haplotypes A and B. Although reference will only be made to haplotypes A and B, the Standard would also apply to new non‐European haplotypes of ‘Ca. L. solanacearum’ which may have different host ranges, or which may be vectored more efficiently by psyllids which are widespread in the region.

The reduction of the risk of spreading ‘Ca. L. solanacearum’ haplotypes C, D and E to potato production systems and potatoes being moved within the EPPO region may be recommended in future when more information is available but is not covered in this Standard.

Specific approval

First approved in 2017‐09.