Creation of a new genus in the family Secoviridae substantiated by sequence variation of newly identified strawberry latent ringspot virus isolates.

To obtain insight into the sequence diversity of strawberry latent ringspot virus (SLRSV), isolates from collections and diagnostic samples were sequenced by high-throughput sequencing. For five SLRSV isolates, the complete genome sequences were determined, and for 18 other isolates nearly complete genome sequences were determined. The sequence data were analysed in relation to sequences of SLRSV and related virus isolates available in the NCBI GenBank database. The genome sequences were annotated, and sequences of the protease-polymerase (Pro-Pol) region and coat proteins (CPs) (large and small CP together) were used for phylogenetic analysis. The amino acid sequences of the Pro-Pol region were very similar, whereas the nucleotide sequences of this region were more variable. The amino acid sequences of the CPs were less similar, which was corroborated by the results of a serological comparison performed using antisera raised against different isolates of SLRSV. Based on these results, we propose that SLRSV and related unassigned viruses be assigned to a new genus within the family Secoviridae, named "Stralarivirus". Based on the phylogenetic analysis, this genus should include at least three viruses, i.e., SLRSV-A, SLRSV-B and lychnis mottle virus. The newly generated sequence data provide a basis for designing molecular tests to screen for SLRSV.

Alstroemeria yellow spot virus (AYSV): a new orthotospovirus species within a growing Eurasian clade.

An orthotospovirus distinct from all other orthotospoviruses was isolated from naturally infected alstroemeria plants. Disease symptoms caused by this virus mainly consisted of yellow spots on the leaves based on which the name alstroemeria yellow spot virus (AYSV) was coined. A host range analysis was performed and a polyclonal antiserum was produced against purified AYSV ribonucleoproteins which only reacted with the homologous antigen and not with any other (established or tentative) orthotospovirus from a selection of American and Asian species. Upon thrips transmission assays the virus was successfully transmitted by a population of Thrips tabaci. The entire nucleotide sequence of the M and S RNA segments was elucidated by a conventional cloning and sequencing strategy, and contained 4797 respectively 2734 nucleotides (nt). Simultaneously, a next generation sequencing (NGS) approach (RNAseq) was employed and generated contigs covering the entire viral tripartite RNA genome. In addition to the M and S RNA nucleotide sequences, the L RNA (8865 nt) was obtained. The nucleocapsid (N) gene encoded by the S RNA of this virus consisted of 819 nucleotides with a deduced N protein of 272 amino acids and by comparative sequence alignments to other established orthotospovirus species showed highest homology (69.5% identity) to the N protein of polygonum ringspot virus. The data altogether support the proposal of AYSV as a new orthotospovirus species within a growing clade of orthotospoviruses that seem to share the Middle East basin as a region of origin.

Characterization of tomato apical stunt viroid isolated from a 24-year old seed lot of Capsicum annuum.

Tomato apical stunt viroid (TASVd) has been identified in a 24-year old seed lot of Capsicum annuum produced in Taiwan. It is the first finding of TASVd in this plant species. The isolate could be discriminated from all reported isolates of TASVd based on its nucleotide sequence, which showed only 94.8% identity with the most related genotype of TASVd. This discrimination was substantiated by phylogenetic analysis. Inoculation of a RNA extract of contaminated seeds to healthy pepper plants showed that the infectivity of the viroid had remained over time. Nevertheless, no transmission to seedlings was observed.

Generic RT-PCR tests for detection and identification of tospoviruses.

A set of tests for generic detection and identification of tospoviruses has been developed. Based on a multiple sequence alignment of the nucleocapsid gene and its 5' upstream untranslated region sequence from 28 different species, primers were designed for RT-PCR detection of tospoviruses from all recognized clades, i.e. the American, Asian and Eurasian clades, and from the small group of distinct and floating species. Pilot experiments on isolates from twenty different species showed that the designed primer sets successfully detected all species by RT-PCR, as confirmed by nucleotide sequence analysis of the amplicons. In a final optimized design, the primers were applied in a setting of five RT-PCR tests. Seven different tospoviruses were successfully identified from diagnostic samples and in addition a non-described tospovirus species from alstroemeria plants. The results demonstrate that the newly developed generic RT-PCR tests provide a relevant tool for broad detection and identification of tospoviruses in plant quarantine and diagnostic laboratories.

A pospiviroid from symptomless portulaca plants closely related to iresine viroid 1.

In symptomless plants of portulaca a potential new pospiviroid was characterized. Analysis by both double and return PAGE showed the presence of a circular RNA. RT-PCR and sequencing revealed a genome of 351 nt with properties characteristic of members of the genus Pospiviroid and with highest sequence identity (circa 80%) with iresine viroid 1 (IrVd-1). The circular RNA from portulaca was shown to replicate independently in its original host, thus showing that it is indeed a viroid. Based on its molecular characteristics, it should be considered a new species. However, since no biological differences have yet been found with its closest relative IrVd-1, the viroid from portulaca does not fulfil all criteria for species demarcation of the ICTV.

Development and validation of a real-time RT-PCR assay for generic detection of pospiviroids.

In many countries phytosanitary regulations apply to Potato spindle tuber viroid, because it can cause serious diseases in potato and tomato crops. Other pospiviroids, some of which are distributed widely in ornamental crops, can cause similar diseases. Consequently, there is a need for a reliable and cost-effective generic testing method. An assay was developed that detects all known species of the genus Pospiviroid, using real-time RT-PCR based on TaqMan technology. This GenPospi assay consists of two reactions running in parallel, the first targeting all pospiviroids, except Columnea latent viroid, the second specifically targeting the latter viroid (already published). To monitor the RNA extraction a nad5 internal control was included. Method validation on tomato leaves showed that the GenPospi assay detects all pospiviroids up to a relative infection rate of 0.13% (equals 770 times dilution). The assay was specific because no cross reactivity was observed with other viroids, viruses or nucleic acid from plant hosts. Repeatability and reproducibility were 100% and the assay appeared robust in an inter-laboratory comparison. The GenPospi assay has been shown to be a suitable tool for large-scale screening for all known pospiviroids. Although it has been validated for tomato leaves it can potentially be used for any crop.

Mexican papita viroid and tomato planta macho viroid belong to a single species in the genus Pospiviroid.

Tomato planta macho viroid (TPMVd) and Mexican papita viroid (MPVd) are two closely related (>90% sequence identity) members of the genus Pospiviroid. Their current status as members of separate species is based upon the reported ability of TPMVd to replicate in Gomphrena globosa and the inability of this viroid to evoke flower break in N. glutinosa. Characterization of a viroid recently isolated from diseased tomato plants grown in Mexico (identical to GenBank accession GQ131573) casts doubt on this earlier report and indicates that these viroids should be classified as members of a single species. Giving priority to the older name, we propose including both of these viroids in the current species Tomato planta macho viroid.

First Report of Iresine viroid 1 in Celosia plumosa in the Netherlands.

In 2008, in the framework of surveying for pospiviroids, nine symptomless clones of Celosia plumosa (Voss) Burv. (Amaranthaceae) from a Dutch breeding company were tested by reverse transcription (RT)-PCR with primer sets Pospi1-RE/FW and Vid-RE/FW (4). In four samples, amplicons of 227 nt were obtained with primers Pospi1-RE/FW. Sequencing of the amplicons showed identities of more than 99% to the partial sequence of Iresine viroid 1 (IrVd-1) from Alternanthera sessilis, NCBI GenBank Accession No DQ846886 (2). Subsequently, a set of primers was designed to amplify the complete viroid genome, i.e., IrVd-FW1 5'-GCG GAA GAA ACA GGA GCT CGW CT-3' and IrVd-RE1 5'-CGC GWG GAG TTC TCC GGT CTT TA-3' - identical to nt 168 to 190 and 145 to 167 of the complete IrVd-1 sequences in the NCBI GenBank (Nos. DQ094293, DQ094294, NC_003613, and X95734). One isolate from C. plumosa was amplified with this primer pair and amplicons were cloned into the pGEM-T Easy Vector System II. Sequencing of one individual cDNA clone (GenBank Accession No. GU911350) revealed a genome size of 370 nt and 98.1% sequence identity to the IrVd-1 isolate from Vinca major, GenBank Accession No. DQ094293 (1). Hence, the viroid was identified as IrVd-1. The isolate from C. plumosa was also mechanically inoculated to 10 healthy plants of C. plumosa, chrysanthemum (Chrysanthemum × morifolium) cv. White Delianne, potato (Solanum tuberosum) cv. Nicola, and tomato (Solanum lycopersicum) cv. Moneymaker. No symptoms were observed over a 6-week period, and RT-PCR with primers Pospi1-RE/FW on bulked samples of five plants per species only identified IrVd-1 in both samples of C. plumosa. For tomato, these results confirm those of Spieker (3). Therefore, in contrast to the other pospiviroids, it seems unlikely that IrVd-1 poses a threat to potato and tomato. References: (1) X. Nie et al. Can. J. Plant Pathol. 27:592, 2005. (2) R. P. Singh et al. Plant Dis. 90:1457, 2006. (3) R. L. Spieker. J. Gen. Virol. 77:2631, 1996. (4) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004.

First Report of Tomato apical stunt viroid in the Symptomless Hosts Lycianthes rantonnetii and Streptosolen jamesonii in the Netherlands.

In 2009, in the framework of surveying for pospiviroids, samples of various ornamental plants from the Netherlands were tested by reverse transcription (RT)-PCR with the primer pairs Pospi1-RE/FW and Vid-RE/FW (2). With primer pair Pospi1-RE/FW, amplicons of the expected size were obtained in two samples of symptomless plants of Lycianthes rantonnetii and Streptosolen jamesonii. Sequencing of the amplicons, which were expected to correspond with partial pospiviroid genomes, showed identities of 100 and 98% to the sequence of Tomato apical stunt viroid (TASVd), NCBI GenBank Accession No. AM777161 (3). For the amplification of the complete viroid genomes, RT-PCRs were performed with primer pair CEVd-FW/RE (1). Sequencing of these amplicons yielded sequences of 364 nt and identities to TASVd AM777161 of 100 and 98.1%, respectively. Therefore, both isolates were identified as TASVd. The sequence variant from S. jamesonii was submitted to the NCBI GenBank as No. GU911351. In addition, both isolates were mechanically inoculated to four tomato plants (Solanum lycopersicum) of cv. Moneymaker. All inoculated plants developed chlorosis and growth reduction after 4 weeks and TASVd infections were confirmed in a bulked sample by RT-PCR with primer pair CEVd-FW/RE after 6 weeks. Hence, two more ornamental host plant species have been identified that may act as symptomless sources of pospiviroid inoculum. References: (1) N. Önelge. Turk. J. Agric. For. 21:419, 1997. (2) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (3) J. Th. J. Verhoeven et al. Plant Dis. 92:973, 2008.

High stability of original predominant pospiviroid genotypes upon mechanical inoculation from ornamentals to potato and tomato.

Eleven pospiviroid isolates from ornamental plants and one from pepper were successfully transmitted to potato and tomato by mechanical inoculation. All isolates with characteristic predominant genotypes were inoculated to a series of potato and tomato plants and propagated for up to four passages. In total, 385 nucleotide sequences were determined, in which 17 new predominant genotypes were identified with minimal differences to the original predominant genotype. In addition, in the original ornamental hosts, only one of eleven predominant pospiviroid genotypes had changed during the experiments over a period of 2 years. These results confirm the high stability of predominant pospiviroid genotypes.

Pepper chat fruit viroid: biological and molecular properties of a proposed new species of the genus Pospiviroid.

In autumn 2006, a new disease was observed in a glasshouse-grown crop of sweet pepper (Capsicum annuum L.) in the Netherlands. Fruit size of the infected plants was reduced up to 50%, and plant growth was also slightly reduced. Here we show that the disease is caused by a previously non-described viroid. The pepper viroid is transmitted by both mechanical inoculation and pepper seeds and, when inoculated experimentally, it infects several solanaceous plant species inducing vein necrosis and reduced fruit and tuber size in tomato and potato, respectively. The viroid RNA genome consists of 348 nucleotides and, with minor modifications, it has the central conserved and the terminal conserved regions characteristic of members of the genus Pospiviroid. Classification of the pepper viroid within the genus Pospiviroid is further supported by the presence and structure of hairpins I and II, the presence of internal and external RY motifs, and phylogenetic analyses. The primary structure of the pepper viroid only showed a maximum of 66% nucleotide sequence identity with other viroids, which is far below the main species demarcation limit of 90%. According to its biological and molecular properties, we propose to assign the pepper viroid to a new species within the genus Pospiviroid, and to name this new species Pepper chat fruit viroid.

First Report of Tomato yellow leaf curl virus in Tomato in the Netherlands.

Tomato yellow leaf curl virus (TYLCV) is an economically important virus with tomato (Solanum lycopersicum L.) as its main host. The virus is widely distributed in subtropical areas and is transmitted by the tobacco whitefly (Bemisia tabaci) in a persistent manner. TYLCV has a quarantine status (IIAII) in the European Union (EU directive 2000/29/EC). It was not previously recorded in the Netherlands. In September 2007, symptoms were observed in tomato crops in a few greenhouses located in close proximity from each other in the western part of the Netherlands. Infected plants showed TYLCV-like symptoms, i.e., stunting, leaf curl, and marginal and interveinal chlorosis. Similar symptoms were evoked after grafting symptomatic tips onto healthy tomato seedlings, whereas no viruses were transmitted by mechanical inoculation to herbaceous test plants. Extracted DNA from symptomatic leaves was used in PCR with two sets of primers for universal detection of begomoviruses (1,2). Analysis of the overlapping amplified products revealed the highest identity to isolate TYLCV-Alm (GenBank Accession No. AJ489258) from Almeria, Spain. To amplify the remaining 60% of the virus genome, three additional primer sets were designed: TYLCV965F 5'-GGCAGCCAAGTACGAGAACC-3' and TYLCV1736R 5'-CCACTATCTTCCTCTGCAATCC-3'; TYLCV1598F 5'-TACTTGCGAACAGTGGCTCG-3' and TYLCV2282R 5'-TCCAAATCGATGGCAGATCAG-3'; TYLCV2229F 5'-ATGCGTCGTTGGCAGATTG-3' and TYLCV68R 5'-CAGTGACGTCTGTGGAACCCT-3'. Analysis of the five overlapping PCR products of one isolate revealed a total virus genome of 2,781 nucleotides. The complete sequence of the Netherlands Isolate (GenBank Accession No. FJ439569) showed 99.3% nucleotide identity to isolate TYLCV-Alm (AJ489258), and therefore, the virus was identified as TYLCV-Alm. After the initial identification, a survey was conducted in all tomato crops in a surrounding area of approximately 40 km2. TYLCV was found in 19 of 27 cultivations. The identity of one isolate per cultivation was confirmed by sequence analysis of the products obtained with the Wyatt and Brown primers (2) occasionally in combination with the Deng primers (with 99.1 to 100% and 99.2 to 100% nucleotide identity to the Netherlands isolate [FJ439569], respectively) (1). As many as 25 symptomatic plants were recorded per greenhouse. A subsequent survey of 34 randomly selected tomato growers in other areas of the country revealed no further infections. Results of the sequence analyses and surveys suggested that the outbreak resulted from a single introduction of the virus, whereas the insect vector B. tabaci accounted for local spread. Measures taken to eliminate the virus included the removal and subsequent destruction of infected tomato plants as well as eradication of B. tabaci. No TYLCV infections were found during surveys in 2008, and therefore, it is believed that the virus was eradicated effectively. References: (1) D. Deng et al. Ann. Appl. Biol. 125:327, 1994. (2) S. D. Wyatt and J. K. Brown. Phytopathology 86:1288, 1996.

First Report of Potato spindle tuber viroid in Cape Gooseberry (Physalis peruviana) from Turkey and Germany.

Since the recent identification of Potato spindle tuber viroid (PSTVd) in vegetatively propagated ornamental plant species (4), many growers have asked to have their mother plants tested for this viroid. In December of 2007, a grower from Turkey submitted cuttings of cape gooseberry (Physalis peruviana) to be tested for PSTVd. Initial testing by real-time reverse transcription (RT)-PCR according to Boonham et al. (1) indicated the presence of either Mexican papita viroid, PSTVd, or Tomato chlorotic dwarf viroid in four samples. To identify the viroid(s) present, isolated RNA from these samples was used for RT-PCR (2), and products of the expected full genome size for the three viroids were amplified from each sample. One of the PCR products was sequenced (GenBank Accession No. EU862230) and analysis of the 357 nt sequence indicated it was most related to PSTVd sequences belonging to the so-called 'Oceanian' strain of the viroid (3), with 99.7% identity to GenBank Accession No. AY962324. Therefore, the viroid was identified as PSTVd. Pathogenicity of this PSTVd genotype was demonstrated when 4 weeks after mechanical inoculation with sap extracts seedlings of tomato cv. Money-maker showed the expected viroid symptoms of chlorosis and stunting, and the presence of the viroid in these plants was confirmed by RT-PCR (2). In March of 2008, by use of RT-PCR (2) and sequencing of the PCR product (GenBank Accession No. EU862231), PSTVd was identified in young seedlings of P. peruviana from a German grower. The German isolate differed at only three nucleotide positions from the Turkish isolate. The identification of PSTVd in young seedlings indicates that seeds had been source of infection, whereas in the case of the PSTVd infected cuttings from Turkey, the infection originated from infected mother plants. To our knowledge, these are the first reports of PSTVd in P. peruviana. Although infected P. peruviana plants did not show symptoms, they might act as sources of inoculum for crops like potato and tomato, which may suffer serious damage. References: (1) N. Boonham et al. J. Virol. Methods 116:139, 2004. (2) A. M. Shamloul et al. Can. J. Plant Pathol. 19:89, 1997. (3) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (4) J. Th. J. Verhoeven et al. Plant Pathol. 57:399, 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.

Recent identifications of Chrysanthemum stunt viroid (CSVd) and Potato spindle tuber viroid (PSTVd) in Solanum jasminoides (3,4) prompted the testing of this plant species for infections with other pospiviroids. From autumn of 2006 to spring of 2007, samples from symptomless plants of S. jasminoides were collected in Belgium (3 samples ranging from 75 to 150 plants), Germany (3 samples ranging from 1 to 200 plants), and the Netherlands (3 samples ranging from 2 to 200 plants). Samples were tested for pospiviroids by reverse transcription (RT)-PCR assays using the Pospi1-FW/RE and Vid-FW/RE (2) and PSTV-Nb-FW (5'-ggatccccggggaaacctgga-3')/RE (5'-ggatccctgaagcgctcctcc-3') primer sets. Each set amplifies several but not all pospiviroids. The first and last primer sets amplified PCR products from six samples. The full-length genomes of all six isolates were amplified using primer pairs CEVd-FW1/RE1 (1) and CEVd-FW2 (5'-gtgctcacctgaccctgcagg-3')/RE2 (5'-accacaggaacctcaagaaag-3'), which are fully complementary to both Citrus exocortis viroid (CEVd) and Tomato apical stunt viroid (TASVd). Sequence analysis of the PCR products identified CEVd from two samples each from Germany and the Netherlands and TASVd from one sample each from Germany and Belgium (plants were imported from Israel). Although the sequences of the different CEVd isolates from S. jasminoides were not identical, all exhibited more than 95% identity with a CEVd isolate from Vicia faba (GenBank Accession No. EF494687). Both TASVd sequences were identical and showed 99.2% identity to a TASVd isolate from tomato (GenBank Accession No. AY 062121). Two nucleotide sequences of CEVd were submitted to the NCBI GenBank (Accession Nos. EU094207 and EU094208). The two other CEVd sequences and the TASVd sequence were submitted to the EMBL Nucleotide Sequence Database as Accession Nos. AM774356, AM774357, and AM777161. In addition to identification from S. jasminoides by sequence analysis, TASVd infection in the S. jasminoides sample from Germany and CEVd in one sample from the Netherlands was confirmed by mechanical inoculation to tomato followed by RT-PCR using the two CEVd-FW/RE primer pairs and analysis of the sequenced PCR product. Infection by CEVd and TASVd was also confirmed in the German samples by Northern hybridization and TASVd was confirmed in the Belgian sample by return-polyacrylamide gel electrophoresis. To our knowledge, these are the first reports of CEVd and TASVd in S. jasminoides. The viroids do not reduce the quality of S. jasminoides plants; however, the infected plants may act as infection sources for other crops. References: (1) N. Önelge. Turk. J. Agric. For. 21:419, 1997. (2) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (3) J. Th. J. Verhoeven et al. Plant Dis. 90:1359, 2006. (4) J. Th. J. Verhoeven et al. Plant Pathol. 57:399, 2008.

First Report of Potato spindle tuber viroid in Tomato in Belgium.

During August of 2006, a sample of a tomato plant (Solanum lycopersicum, formerly Lycopersicum esculentum) from a greenhouse in Belgium was received for diagnosis. The plant showed severe growth reduction and the young leaves were chlorotic and distorted. In the greenhouse, the disease had been spreading slowly along the row. These observations suggested the presence of a viroid infection, and reverse transcriptase (RT)-PCR with two sets of universal pospiviroid primers (Pospi1-RE/FW and Vid-FW/RE; 3) yielded amplicons of the expected size (approximately 196 and 360 bp). Sequence analysis of the larger PCR product revealed that the genome was 358 nt and 100% identical to two isolates of Potato spindle tuber viroid (PSTVd) previously submitted to the NCBI GenBank (Accession Nos. AJ583449 from the United Kingdom and AY962324 from Australia). A pathogen associated with the symptomatic tomato plants was therefore identified as PSTVd. Tracing the origin of the infection revealed the following information: during November of 2005, 8-day-old tomato seedlings raised from seed by a Dutch nursery were transferred to a small part of the greenhouse of the Belgian grower; 7 to 8 weeks later, the plants were transplanted to their final destination; during May of 2006, the grower first observed growth reduction in a single plant; several weeks later, similar symptoms were observed in two more plants in the same row close to the first symptomatic plant; and by September, there were approximately 20 symptomatic tomato plants, all located in two adjacent rows. The viroid outbreak was fully eradicated by destroying all tomato plants in the affected rows as well as in two adjacent rows at both sides. The absence of further infections was confirmed by testing approximately 1,200 tomato plants in pooled samples for PSTVd by RT-PCR (2) and real-time RT-PCR (1). The origin and the method of introduction and spread of the viroid remain unclear. References: (1) N. Boonham et al. J. Virol. Methods 116:139, 2004. (2) R. A. Mumford et al. Plant Pathol. 53:242, 2004. (3) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004.

First Report of Tomato chlorotic dwarf viroid in Petunia hybrida from the United States of America.

In November 2005, 13 accessions of Petunia hybrida from the United States of America entered the post-entry quarantine station of the Plant Protection Service in the Netherlands. The plants were inspected and tested for quarantine organisms according to Directives 95/44 and 97/46 of the European Union. No virus and viroid symptoms were observed in the imported plants or in mechanically inoculated plants of Chenopodium quinoa, Nicotiana benthamiana, and N. occidentalis-P1 (3). Testing for pospiviroids by return-polyacrylamide gel electrophoresis (1) and reverse transcriptase-PCR with universal pospiviroid primers Pospi1-RE/FW (2) indicated the presence of pospiviroids in 3 and 11 P. hybrida accessions, respectively. The 196-bp amplicons of six accessions were sequenced. Sequence analysis showed the highest identity for all amplicons to both isolates of Tomato chlorotic dwarf viroid (TCDVd) in NCBI GenBank, Accession Nos. AF162131and AY372399, from Canada and the United States, respectively. Additional RT-PCRs with the Pospi1-RE/FW primers in opposite order and the semi-universal pospiviroid primers Vid-RE/FW (2) for one isolate, followed by sequence analysis, confirmed the identity as TCDVd. The isolate consisted of 359 nucleotides (GenBank Accession No. DQ859013) and showed sequence identities of 98.6 and 96.1% to the Canadian and American tomato isolates of this viroid, respectively. The next highest sequence identity was 90.0% to two accessions of Potato spindle tuber viroid (GenBank Accession Nos. AJ593449 and AY962324). On the basis of these results, the viroid from P. hybrida was identified as TCDVd. To our knowledge, this is the first report of TCDVd in this plant species. Reference: (1) J. W. Roenhorst et al. EPPO Bull. 30:453, 2000. (2) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (3) J. Th. J. Verhoeven and J. W. Roenhorst. EPPO Bull. 33:305, 2003.

First Report of Potato virus M and Chrysanthemum stunt viroid in Solanum jasminoides.

In 2005, a plant of the ornamental crop Solanum jasminoides from the Netherlands was submitted for testing on viruses and viroids because of its intended use for propagation. Sap from this plant was mechanically inoculated to the test plant species Chenopodium quinoa, Nicotiana benthamiana, N. hesperis-67A, and N. occidentalis-P1 (3). N. hesperis-67A showed chlorotic local lesions and rugosity followed by vein necrosis, N. occidentalis-P1 showed necrotic local lesions and systemic leaf distortion, and the two other test plant species remained symptomless. Potato virus M (PVM) was identified by double antibody sandwich enzyme-linked immunosorbent assay using leaves from S. jasminoides and N. hesperis-67A. The plant of S. jasminoides was also tested for the presence of viroids by reverse transcriptase-polymerase chain reaction (RT-PCR) with universal pospiviroid primers Pospi1-RE/FW (2). This reaction yielded an amplicon of the expected size of 198 bp. The sequence showed 100% identity to an isolate of Chrysanthemum stunt viroid (CSVd; NCBI GenBank Accession No. AF394453). Subsequently, the complete sequence of our viroid isolate (GenBank Accession No. DQ406591) was determined from the amplicon obtained after RT-PCR using specific primers for the detection of CSVd (1). The viroid isolate from S. jasminoides consisted of 354 nucleotides and showed the highest identity (98.6%) to a chrysanthemum isolate of CSVd (GenBank Accession No. AB055974). Therefore, the viroid was identified as CSVd. To our knowledge, this is the first report of PVM and CSVd in S. jasminoides. Reference: (1) R. Hooftman et al. Acta Hortic. 432:120, 1996. (2) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004. (3) J. Th. J. Verhoeven and J. W. Roenhorst, EPPO Bull. 33:305, 2003.

First Report of Tomato apical stunt viroid in Tomato in Tunisia.

In May 2005, the Plant Protection Service in the Netherlands received two tomato (Lycopersicon esculentum) plant specimens for diagnosis from a protected crop production facility of 2.5 ha near Kebili in Tunisia. Growth of the plants was reduced and leaves were chlorotic and brittle. Ripening of the fruits was delayed and their storage life was reduced from 3 weeks to 1 week. The grower reported that initially only 5% of plants showed symptoms; however, the number of symptomatic plants increased quickly to 100% as a result of increasing temperatures in the production facility. Test plant species Chenopodium quinoa, Datura stramonium, Nicotiana glutinosa, N. hesperis-67A, N. occidentalis-P1, and L. esculentum 'Money-maker' were mechanically inoculated with sap from the affected plants. Symptoms including chlorosis and stunting were observed only on L. esculentum. Reverse transcriptase-polymerase chain reaction (RT-PCR) with universal pospiviroid primers Pospi1-RE/FW (2) yielded amplicons of the expected size (196 bp) for each of the two samples. One of these amplicons was sequenced and showed the highest identity to the four isolates of Tomato apical stunt viroid (TASVd) in the NCBI Gen-Bank. Subsequently, the complete sequence of the Tunisian isolate (Gen-Bank Accession No. DQ144506) was determined by sequencing the am-plicon obtained after RT-PCR using primers developed for the detection of Citrus exocortis viroid (CEVd) (1). The isolate consisted of 363 nucleotides and showed the highest sequence identity (96.7%) to tomato isolates of TASVd from Indonesia and Israel (GenBank Accession Nos. X06390 and AY062121, respectively), 92.6% to a tomato isolate from the Ivory Coast (GenBank Accession No. K00818), and 87.7% to an isolate from Solanum pseudocapsicum (GenBank Accession No. X95293). The next highest sequence identity was 81.5% to an isolate of CEVd (GenBank Accession No. X53716). On the basis of these results, the viroid was identified as TASVd. To our knowledge, this is the first report of TASVd in Tunisia. Reference: (1) N. Önelge. Turkish J. Agric. For. 21:419, 1997. (2) J. Th. J. Verhoeven et al. Eur. J. Plant Pathol. 110:823, 2004.

First Report of Tomato infectious chlorosis virus in Tomato in Indonesia.

In 2002, a breeding company submitted several samples of tomato (Lycopersicon esculentum) for diagnosis. Samples originated in Indonesia and were taken from protected and nonprotected crops. Plants exhibited severe chlorosis on fully expanded leaves, while young leaves were symptomless. Symptoms resembled those of the criniviruses Tomato chlorosis virus (ToCV) and Tomato infectious chlorosis virus (TICV). Moreover, large numbers of whiteflies, potential vectors of these viruses, had been observed at the plots with symptomatic plants. A reverse transcription-polymerase chain reaction (RT-PCR) with specific primers for TICV (1) yielded amplicons of the expected size of approximately 500 bp for all samples. One of the amplicons was sequenced (Genbank Accession No. AY221097) and revealed more than 98.9% identity to six isolates of TICV in NCBI Genbank. cDNA synthesis using the universal crinivirus primer HSP_M2-DW (5' -TCRAARGTWCCKCCNCCRAA-3') followed by PCR with a ToCV specific primerset (ToCV-UP 5'-TCATTAAAACTCAATGGGACCGAG-3' and ToCV-DW 5'-GCGACGT AAATTGAAACCC-3') was negative in all cases. Grafting of symptomatic shoots onto healthy tomato seedlings of cv. Money-maker showed transmission of the virus, as chlorosis appeared on fully expanded leaves of lateral shoots after 6 weeks. The presence of TICV in the graft-inoculated plants was confirmed by RT-PCR. Furthermore, mechanical inoculation to a range of herbaceous test plants did not evoke any virus symptoms, indicating the absence of mechanically transmissible viruses. Although other nonmechanically transmissible viruses cannot be fully excluded, the results together with the symptoms observed, indicate that TICV is the cause of the disease. TICV has been reported from Greece, Italy, Japan, Spain, and the United States, but to our knowledge, this is the first report of TICV in Indonesia. Reference: (1) A. M. Vaira et al. Phytoparasitica 30:290, 2002.

First Report of Pepper mottle virus in Tomato.

In 2000, a breeding company submitted a tomato (Lycopersicon esculentum) sample from Guatemala for diagnosis. The plants showed necrotic lesions on leaves surrounded by some chlorosis, necrotic streaks on stems, and large superficial necrotic lesions on fruits. By mechanical inoculation of plant sap to different plant species, symptoms appeared in Capsicum annuum 'Westlandse Grote Zoete', Lycopersicon esculentum 'Money-maker', Nicotiana benthamiana, N. bigelovii, N. glutinosa, N. hesperis-67A, N. occidentalis-P1, N. tabacum 'White Burley', and Physalis floridana. Systemically infected leaves from N. occidentalis-P1 were used for all further experiments. Leaf dip preparations were analyzed by transmission electron microscopy and revealed the presence of filamentous virus particles typical of a potyvirus. Double-antibody sandwich enzyme-linked immunosorbent assay tests for Potato virus A, V, and Y, Tobacco etch virus, and Wild potato mosaic virus were negative. An antiserum (PepMoV/DSMZ As 0186) to Pepper mottle virus (PepMoV), however, gave a positive reaction. To obtain further evidence for the presence of this virus, the nucleotide sequence of the complete 3' nontranslated region (3NTR) and the 3' terminal part of the coat protein gene (3CPG) was determined using the set of degenerate primers P9502/CPUP (1). The obtained nucleotide sequence (approximately 700 bp) was deposited in GenBank under Accession No. AF440801. It showed 93 to 94% 3NTR and 90 to 93% 3CPG homology with the three sequences of PepMoV from pepper already present in GenBank. The two viruses with the next closest nucleotide sequence homology were Potato virus V and Potato virus Y showing up to 80 and 75% homology with the 3CPG and up to 53 and 48% homology with the 3NTR, respectively. Based on these results, we concluded that the virus isolated from the symptomatic tomato plants was PepMoV. Because of the relatively low homologies with the pepper isolates of PepMoV, this tomato isolate might be a separate strain of the virus. To our knowledge, this is the first report of the occurrence of PepMoV in tomato. Reference: (1) R. A. A. van der Vlugt et al. Phytopathology 89:148, 1999.