Comparison of diagnostic techniques for the detection and differentiation of Cherry leaf roll virus strains for quarantine purposes.

Some strains of Cherry leaf roll virus (CLRV) are considered as quarantine pests in New Zealand. CLRV was detected in seven plant host species: Actinidia chinensis, Hydrangea macrophylla, Malus domestica, Plantago major, Ribes rubrum, Rubus idaeus and Rumex sp. collected from New Zealand between 2005 and 2012. Biological, serological and molecular techniques were compared for the detection and differentiation of CLRV isolates. The biological analysis revealed differences in symptomatology and disease severity among the isolates. The five isolates tested by ELISA were serologically related to each other using polyclonal antisera with only one out of four commercially-available antisera successfully detecting all of them. The phylogenetic analysis of sequences obtained from parts of the coat protein, polymerase and 3'-untranslated regions revealed that the New Zealand CLRV isolates clustered into two closely related but distinct phylogenetic groups with some isolates grouping differently depending on the gene studied. The New Zealand CLRV isolates were clearly distinct to overseas isolates found in phylogenetic groups A, D and E. The conventional RT-PCR using primers targeting the CLRV coat protein coding region is recommended for determining sequence differences between strains. These findings will be useful in making regulatory decisions with regard to the testing requirements and the CLRV strains to be regulated in New Zealand.

First Report of Cherry leaf roll virus in Hydrangea macrophylla.

Hydrangea is a popular, summer flowering, ornamental shrub that is native to south and east Asia and North and South America, which is now cultivated throughout the world. Currently, 13 viruses belonging to eight genera have been reported in Hydrangea spp. (1). In April 2011, virus-like disease symptoms, including severe leaf deformation and chlorosis, were observed on two Hydrangea macrophylla 'Sumiko' plants from Australia being held in quarantine in New Zealand. Systemic symptoms of veinal necrosis, necrotic halo spots, and severe leaf deformation were observed on Nicotiana occidentalis '37B' 7 days after inoculation with sap from the symptomatic hydrangea plants. Upon reinoculation with sap of symptomatic leaves from N. occidentalis, necrotic ringspots and tip necrosis, typical of nepovirus infection, were observed on leaves of N. tobacum and Chenopodium quinoa, respectively. Transmission electron microscopy of negatively stained sap from symptomatic leaves of N. occidentalis revealed the presence of isometric particles ~28 nm in diameter. Total nucleic acid was extracted from the symptomatic leaves of N. occidentalis with an InviMag Plant DNA Mini Kit (Invitek GmbH, Berlin, Germany) and a KingFisher mL workstation (Thermo Scientific, Waltham, MA). Reverse transcription (RT)-PCR using the reverse primer of Werner et al. (2) and a forward primer, 5'-CGGTGGAGATGCCGGTCCTA-3' (this study), specific to the 3'-untranslated region (3'-UTR) of Cherry leaf roll virus(CLRV) produced an amplicon of ~1,150 bp from N. occidentalis. A consensus sequence of 1,140 bp generated from four clones of the PCR product (GenBank Accession No. JN418885) was 99 and 98% identical at the nucleotide level to a CLRV isolate from Rumex AGBC (GenBank No. AB168099) and Chinese chives (GenBank No. AB168098), respectively. N. occidentalis also tested positive for CLRV using polyclonal antiserum in a double antibody sandwich-ELISA (BIOREBA, Reinach, Switzerland). The presence of CLRV in the original samples and N. occidentalis was confirmed by direct sequencing of the 380-bp amplicons obtained by immunocapture RT-PCR using CLRV-specific primers (2) and the same antiserum. BLASTn analysis of these amplicons (data not submitted to GenBank) also showed 99% nucleotide identity to a New Zealand isolate from a Rubus sp. (GenBank No. AJ877162). The hydrangea plants were released from quarantine because the same strain of CLRV had previously been reported in New Zealand. To our knowledge, this is the first report of CLRV in hydrangea. CLRV is a seed and pollenborne nepovirus and can be transmitted mechanically and by grafting. Since hydrangeas are mainly vegetatively propagated and are less commonly grown from seeds, the natural spread of CLRV will depend on the movement of infected propagation material. It is unknown whether this virus causes reduction in flower quality in hydrangea as reported in other hosts but any impact on flower quality may be of economic significance in commercial nurseries. References: (1) M. Caballero et al. Plant Dis. 93:891, 2009. (2) R. Werner et al. Eur. J. For. Pathol. 27:309, 1997.

First Report of a Carlavirus in Fuchsia spp. in New Zealand.

The genus Fuchsia has 110 known species and numerous hybrids. These ornamental plants with brightly colored flowers originate from Central and South America, New Zealand, and Tahiti, but a wider variety are now grown all over the world. Few viruses have been reported in Fuchsia spp.: a carlavirus, Fuchsia latent virus (FLV) (1-3), a cucumovirus, Cucumber mosaic virus (CMV) (3), and two tospoviruses, Impatiens necrotic spot virus (INSV) and Tomato spotted wilt virus (TSWV) (4). In August 2009, five plants, each representing a different cultivar of Fuchsia hybrid, from home gardens in the Auckland and Southland regions of New Zealand, displayed variable symptoms including mild chlorosis, mild mottle, or purple spots on leaves. Plants tested negative for CMV, INSV, and TSWV using commercial ImmunoStrips (Agdia Inc., Elkhart, IN); however, flexuous particles of ~650 to 700 nm were found by electron microscopy in all samples. Local lesions were also observed on Chenopodium quinoa plants 4 weeks after sap inoculation. Total RNA was extracted from all plants with a RNeasy Plant Mini Kit (Qiagen Inc., Doncaster, Australia) and tested by reverse transcription (RT)-PCR using two generic sets of primers (R. van der Vlugt, personal communication) designed to amplify fragments of ~730 and 550 bp of the replicase and coat protein genes of carlaviruses, respectively. Amplicons of the expected size were obtained for all samples, cloned, and at least three clones per sample were sequenced. No differences within clones from the same samples were observed (GenBank Accession Nos. HQ197672 to HQ197681). A BLASTn search of the viral replicase fragment showed the highest nucleotide identity (76%) to Potato rough dwarf virus (PRDV) (EU020009), whereas the coat protein fragment had maximum nucleotide identity (70 to 72%) to PRDV (EU020009 and DQ640311) and Potato virus P (DQ516055). Sequences obtained were also pairwise aligned using the MegAlign program (DNASTAR, Inc., Madison, WI) and results showed that the isolates had 83 to 97% identity to each other within each genome region. Further sequences (HQ197925 and HQ197926) were obtained from a Fuchsia plant originating from Belgium, a BLASTn analysis showed high nucleotide identity (84 to 99%) to the New Zealand isolates. The low genetic identity to other Carlavirus members suggests that these isolates belong to a different species from those previously sequenced. On the basis of electron microscopy and herbaceous indexing, the isolates had similar characteristics to a carlavirus reported from Fuchsia in Italy (1) and FLV reported in Canada (2). The Italian carlavirus isolate was obtained and tested with the same primers by RT-PCR. Pairwise analysis of the Italian sequences (HQ197927 and HQ197928) with the New Zealand and Belgian sequences showed between 84 and 95% similarity within each genome region. These results suggest that the carlavirus infecting these plants is the same virus, possibly FLV. To our knowledge, this is the first report of this carlavirus infecting Fuchsia spp. in New Zealand, but the virus has probably been present for some time in this country and is likely to be distributed worldwide. References: (1) G. Dellavalle et al. Acta Hortic. 432:332, 1996. (2) L. J. John et al. Acta Hortic. 110:195, 1980. (3) P. Roggero et al. Plant Pathol. 49:802, 2000. (4) R. Wick and B. Dicklow. Diseases in Fuchsia. Common Names of Plant Diseases. Online publication. The American Phytopathological Society, St. Paul, MN, 1999.

First Molecular Evidence of Citrus psorosis virus and Citrus viroid III from Citrus spp. in New Zealand.

In December 2008, a collection of Citrus spp. in Kerikeri, New Zealand was surveyed for virus and viroid diseases. Symptoms characteristic of virus or viroid infection were not observed other than Citrus tristeza virus (CTV)-associated stem pitting when examined with the bark removed. Total RNA was extracted from bark samples of 273 trees using RLT buffer (Qiagen Inc., Chatsworth, CA) on a KingFisher mL workstation (Thermo Scientific, Waltham, MA) and tested by reverse transcription (RT)-PCR). Samples from three trees, two from sweet orange, Citrus × sinensis (L.) Osbeck (pro sp.) (maxima × reticulate) and one from tangerine, Citrus reticulata Blanco, tested positive for Citrus psorosis virus (CPsV), and two samples, one each from lemon, Citrus × limon (L.) Burm. F. (pro sp.) (medica × aurantifolia) and sweet orange, tested positive for Citrus viroid III (CVd-III) using previously published primers and PCR cycling conditions (2,4) in a one-step RT-PCR system. The 20-µl RT-PCR reaction was done with Verso Reddymix reagents (Thermo Scientific) containing 250 nM of specific primers and 300 µg/µl of bovine serum albumin (Sigma-Aldrich, St. Louis, MO). The CVd-III genome was completed using specific internal primers (forward: 5'-AACGCAGAGAGGGAAAGGGAA-3', reverse: 5'-TAGGGCTACTTCCCGTGGTC-3') with the following cycling conditions: 50°C for 15 min, 94°C for 2 min, then 40 cycles of 94°C for 10 s, 57°C for 30 s, and 68°C for 30 s. The three CPsV amplicons of 419 bp from the RNA-dependent RNA polymerase gene (GenBank Accession Nos. GQ388241 to GQ388243) had 96 to 100% nucleotide identity to each other. A 276-bp (nt position 48 to 323) fragment of the 419-bp sequence was used for comparison with sequences available on GenBank. The three 276-bp CPsV sequences had 89 to 97% nucleotide identity to other CPsV available in GenBank at the time of the analysis. The CVd-III genomes of 291 bp (GenBank Accession Nos. HQ219183 and JF521494) are identical and showed 94 to 99% nucleotide identity to other CVd-III available in GenBank. The presence of CPsV was confirmed in the three samples by a CPsV-specific double-antibody sandwich-ELISA kit (Agritest S.r.l., Valenzano, Italy), while the presence of CVd-III was confirmed only in the lemon sample by r-PAGE (3). The concentration of the viroid in the sweet orange sample may have been below the detection limit of the test. The incidence of the diseases is probably low since CPsV and CVd-III were detected in only a few trees which were planted between 1998 and 2002 at Kerikeri from budwoods of unknown sources imported between the 1970s and 1990s. New Zealand's growing conditions generally do not favor viroid replication in plants, whereas the temperatures may be suitable for CPsV disease. However, symptom characteristics to CPsV and CVd-III have never been observed on the infected trees. This is most likely because of the presence of CTV in the trees (data not shown). CPsV symptoms were thought to have been observed in the 1950s in New Zealand (1) but the causal agent had not been identified. To our knowledge, this is the first molecular and serological evidence of CPsV and the first report of the presence of CVd-III in New Zealand. References: (1) W. A. Fletcher. Orchard. N. Z. 30:33, 1957. (2) T. Ito et al. J. Virol. Methods 106:235, 2002. (3) C. Jeffries and C. James. OEPP/EPPO Bull. 35:125, 2005. (4) S. Martin et al. J. Gen. Virol. 87:3097, 2006.

First Report of Potato spindle tuber viroid in Cape Gooseberry (Physalis peruviana) in New Zealand.

In February 2009, 10 cape gooseberry plants (Physalis peruviana) grown from seed on a domestic property in Christchurch, New Zealand, showed severe leaf distortion, fasciation and etiolation of growing tips, and weak flowering. Symptoms were first observed in the emerging seedlings. No virus particles were observed in sap from infected plants with the electron microscope. Total RNA was isolated from leaves of the 10 plants with a Qiagen RNeasy Plant Mini Kit (Valencia, CA). All 10 plants tested positive for Potato spindle tuber viroid (PSTVd) by real-time reverse transcription (RT)-PCR (1) and by RT-PCR with PSTVd-specific primers (3) and generic pospiviroid primers (4). For both conventional PCRs, the expected 359-bp amplicons were sequenced directly and sequences were aligned together to create a consensus sequence (GenBank Accession No. FJ797614). BLASTn analysis showed 98% nucleotide identity to PSTVd (EU862231, DQ308556, X17268, and AY532801-AY532804). Sap from one of the infected plants was mechanically inoculated onto healthy P. peruviana, Solanum lycopersicum 'Rutgers', Chenopodium amaranticolor, C. quinoa, Cucumis sativum 'Crystal Apple', Gomphrena globosa, Nicotiana benthamiana, N. clevelandii, N. occidentalis '37B', N. tabacum 'WB', N. sylvestris, and Phaseolus vulgaris 'Prince'. After 4 weeks, the leaves of the 'Rutgers' tomato plants were showing severe distortion, purpling, and necrosis of mid-veins and P. peruviana plants were showing distortion of newly emerging apical leaves. Healthy control P. peruviana were asymptomatic. Symptoms appeared milder than that observed in the original P. peruviana plants, but this may be related to different environmental conditions or age or growth stage of the plants when inoculated. All other indicator plants were symptomless, but along with P. peruviana, tested positive for PSTVd by real-time RT-PCR (1). The presence of PSTVd was further confirmed in one original symptomatic and the mechanically inoculated P. peruviana plants and in the indicator plants by dot-blot hybridization with a digoxygenin-labeled synthetic ssRNA probe specific to the full-length PSTVd genome. PSTVd has been reported in New Zealand previously in commercial glasshouse crops of tomatoes and peppers (2), but was eradicated and so remains a regulated pest. The plants were grown from seeds imported from Germany and it is possible that the infection was seedborne. PSTVd was reported in young cape gooseberry seedlings in Germany and Turkey but the infection was asymptomatic (5). Symptoms were associated with the PSTVd-infected cape gooseberry in New Zealand. To our knowledge, this is the first report of the viroid in domestically grown plants in New Zealand, and only the second report of PSTVd in cape gooseberry worldwide. Our findings suggest that this species is an emerging host for PSTVd and that dissemination of seed may provide a pathway for international movement of the viroid. References: (1) N. Boonham et al. J. Virol. Methods 116:139, 2004. (2) B. S. M. Lebas et al. Australas. Plant Pathol. 34:129, 2005. (3) A. M. Shamoul et al. Can. J. Plant Pathol. 19:89, 1997. (4) J. T. H. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (5) J. T. H. Verhoeven et al. Plant Dis. 93:316, 2009.

First Report of 'Candidatus Phytoplasma australiense' in Potato.

In January of 2009, potato plants (Solanum tuberosum) from a commercial crop in the Waikato Region, New Zealand were observed to have symptoms of upward rolling and purpling of the leaves. The symptoms appeared similar to those of "zebra chip", a disorder of potato recently found to be associated with 'Candidatus Liberibacter solanacearum' in New Zealand and the United States (4). Total DNA from the leaf midveins and tubers from one of the symptomatic plants was separately extracted with an InviMag Plant DNA Mini Kit (Invitek GmbH, Berlin, Germany) and a KingFisher mL workstation (Thermo Scientific, Waltham, MA). DNA extracted from leaf midveins and tubers tested negative for 'Ca. L. solanacearum' by nested-PCR using primer pair OA2/OI2c (4) followed by Lib16S01F/Lib16S01R (5'-TTCTACGGGATAACGCACGG-3' and 5'-CGTCAGTATCAGGCCAGTGAG-3'), which amplifies a 580-bp region of the 16S rRNA gene. However, DNA extracted from the tuber tissue tested positive for phytoplasma by TaqMan real-time PCR (3). No phytoplasma was detected in the DNA extracted from leaf tissue. The 16S rRNA gene, 16S-23S rRNA intergenic spacer region, and part of the 23S rRNA gene of the phytoplasma were amplified with primers P1/P7 (1). The PCR product was cloned into the pCR 4-TOPO vector (Invitrogen, Carlsbad, CA) and sequenced (GenBank Accession No. FJ943262). BLAST analysis showed 100% identity to 'Ca. Phytoplasma australiense' (16SrXII, Stolbur group). A fragment of approximately 850-bp of the Tuf gene was also amplified (2) and sequenced directly (GenBank Accession No. FJ943263). BLAST analysis showed 100% identity to Tuf gene variant IX of 'Ca. P. australiense' (2). An additional 14 plants showing similar leaf symptoms and also production of aerial tubers were collected from seven different potato fields from the Auckland and Waikato regions. Total DNA from the leaf midveins, stem, and tubers were separately extracted from each of the plants. The samples were tested for phytoplasma by nested-PCR using primer pair R16F2/R16R2, followed by NGF/NGR (1), and tested for 'Ca. L. solanacearum' by nested-PCR as described above. Seven plants tested positive only for phytoplasma, three tested positive for only 'Ca. L. solanacearum', and four plants tested positive for both pathogens. The pathogens were most commonly detected in samples extracted from the stem with 9 and 5 of the 14 samples testing positive for phytoplasma and liberibacter, respectively. Six of each of the leaf and tuber samples tested positive for phytoplasma. Liberibacter was detected in one of the leaf samples and in four of the tuber samples. 'Ca. P. australiense' has only been reported from New Zealand and Australia. The only other known hosts of 'Ca. P. australiense' in New Zealand are strawberry and native plants belonging to the genera Cordyline, Coprosma, and Phormium (2). In Australia, 'Ca. P. australiense' is associated with Australian grapevine yellows and Papaya dieback (2). To our knowledge, this is the first report of 'Ca. P. australiense' infecting potato as well as the first report of phytoplasma and 'Ca. L. solanacearum' mixed infections in potato. References: (1) M. T. Andersen et al. Plant Pathol. 47:188, 1998. (2) M. T. Andersen et al. Phytopathology 96:838, 2006. (3) N. M. Christensen et al. Mol. Plant Microbe Interact. 17:1175, 2004. (4) L. W. Liefting et al. Plant Dis. 93:208, 2009.

First Report of Narcissus degeneration virus, Narcissus late season yellows virus, and Narcissus symptomless virus on Narcissus in New Zealand.

In September 2008, Narcissus plants originating from commercial nurseries in Taranaki (TK) in New Zealand's North Island and Canterbury (CB) in the South Island were received showing leaf mottling, flower distortion, and color break. The CB plant also showed stunting. Filamentous virus particles (700 to 900 nm long) were seen in crude sap of both plants with a transmission electron microscope. Total RNA was isolated from the leaves of both plants with an RNeasy Plant Mini Kit (Qiagen, Chatsworth, CA), and cDNA was synthesized by Superscript III (Invitrogen, Carlsbad, CA). cDNA was used in PCR to test for viruses in the following genera: Allexivirus, Carlavirus, Cucumovirus, Nepovirus A and B, Potyvirus, Potexvirus, Tospovirus, and Tobravirus. Both plants tested positive for potyvirus using generic potyvirus primers (3). Amplicons from both plants were directly sequenced. The forward and reverse sequence from the CB plant matched sequences in the GenBank database for Narcissus late season yellows virus (NLSYV) and Narcissus degeneration virus (NDV), respectively. The potyvirus amplicon from the CB plant was cloned and sequenced. Sequence from independent clones was obtained for NLYSV only (No. FJ546721), and this sequence showed 97% nucleotide identity to NLYSV No. EU887015. The CB plant was tested with a second set of generic potyvirus primers using forward (PV1SP6) (2) and reverse primers (U335) (1). BLASTN analysis of the sequence obtained from independent clones (No. FJ543718) matched sequence for NDV only (97% nucleotide identity to No. AM182028). BLASTN analysis of the potyvirus obtained for the TK plant (No. FJ546720) showed 97% nucleotide identity to NLSYV (No. EU887015). The TK plant also tested positive for a carlavirus using commercial primers (Agdia, Elkhart, IN) and unpublished generic carlavirus primers (A. Blowers, personal communication). Amplicons from both PCRs were cloned and sequenced. BLASTN analysis of both sequences (Nos. FJ546719 and GQ205442) showed 94% nucleotide identity to Narcissus symptomless virus (NSV) No. AM182569. Both plants were also tested for NLSYV, Narcissus virus Q, Narcissus latent virus, and Narcissus yellow stripe virus by indirect ELISA (Neogen, Lansing, MI). Results confirmed the presence of NLSYV in both plants but the plants were negative for the other viruses. NLSYV has been detected previously from Narcissus pseudonarcissus L. (daffodil) (D. Hunter, personal communication); however, to our knowledge, this is the first official report of NDV, NLSYV, and NSV in New Zealand. Since both plants tested negative for several other viruses by PCR and ELISA, this would suggest that the symptoms observed may have been caused by NSV, NLSYV, NDV, or as a result of a mixed infection. However, symptoms were not confirmed using Koch's postulate. NSV has been reported in the literature as symptomless. NLYSV has been reported to be a possible cause of leaf chlorosis and striping and NDV has been associated with chlorotic leaf striping in N. tazetta plants (4). Since Narcissus is an important flower crop for domestic production in New Zealand, the reduction in flower quality observed when these viruses are present may be of economic significance in commercial nurseries. References: (1) S. A. Langeveld et al. J. Gen. Virol. 72:1531, 1991. (2) A. M. Mackenzie et al. Arch Virol. 143:903, 1998. (3) V. Marie-Jeanne et al. J. Phytopathol. 148:141, 2000. (4) W. P. Mowat et al. Ann. Appl. Biol. 113:531, 1988.