Sequence analysis of RNA 2 and RNA 3 of lilac leaf chlorosis virus: a putative new member of the genus Ilarvirus.

RNA 2 and RNA 3 of lilac leaf chlorosis virus (LLCV) were sequenced and shown to be 2,762 nucleotides (nt) and 2,117 nts in length, respectively. RNA 2 encodes a putative 807-amino-acid (aa) RNA-dependent RNA polymerase associated protein with an estimated M (r) of 92.75 kDa. RNA 3 is bicistronic, with ORF1 encoding a putative movement protein (277 aa, M (r) 31.45 kDa) and ORF2 encoding the putative coat protein (221 aa, M (r) 24.37 kDa). The genome organization is similar to that typical for members of the genus Ilarvirus. Phylogenetic analyses indicate a close evolutionary relationship between LLCV, ApMV, and PNRSV.

First Report of Colombian datura virus in Brugmansia in Canada.

Colombian datura virus (CDV) was first described in 1968 (3) and has since been reported in Europe (4), Japan (see 4 for additional references), and the United States (1,2). CDV is a member of the family Potyviridae with flexuous, filamentous nucleocapsids that can be transmitted by mechanical inoculation and grafting and is known to be vectored by the common aphid Myzus persicae. In the fall of 2007, five Brugmansia plants of unknown species from a Parks Board Collection in a Lower Mainland nursery, British Columbia, Canada, were found to be displaying symptoms typical of a viral infection: chlorotic flecking and mottling on leaves, leaf shrivel, and vein banding. Symptomatic leaves from these five plants were tested by ELISA (Immuno Strip Test, Agdia, Elkhart, IN) for several common viruses including Impatiens necrotic spot, Tobacco mosaic, Cucumber mosaic, and Tomato spotted wilt viruses and found to be negative for all. However, rub inoculations onto the herbaceous indicators Nicotiana occidentalis and N. benthamiana resulted in severe symptom formation including necrosis, wilting, shriveling, stunted growth, petiole and stem tip collapse, as well as collapse from the base of the plants, and plant death within 2 weeks after inoculation. A leaf dip assay of the original infected Brugmansia sample and infected N. benthamiana tissue revealed flexuous, potyvirus-like particles with the electron microscope (EM). On the basis of the Brugmansia leaf symptoms and the EM results, a possible infection with CDV was suspected. Primers CDV-3 and CDV-NIb5, specific to CDV (4), were used in a reverse transcription (RT)-PCR assay that amplified an approximate 1,600-bp fragment from the original Brugmansia sample and inoculated N. bentamiana and N. occidentalis plants. The amplified portion of the genome is the extreme 3' terminus and includes the 3' noncoding sequence, the viral coat protein gene, and part of the viral replicase gene. Fragments were cloned into pCR2.1-TOPO (Invitrogen, San Diego, CA) and two clones from each plant (total of six clones) were sequenced in both directions. Sequences of all clones were essentially identical, with only three nucleotide differences among the clones (GenBank Accession No. EU571230). BLASTn analysis revealed the highest match to several CDV isolates ranging from 98.7 to 99.5% nucleotide sequence identity. BLASTp analysis of the 451 amino acid viral polyprotein translation product gave a similarly high match with CDV isolates, with the highest match to a Hungarian isolate of CDV (GenBank Accession No. CAD26690) of 99.8% identity, or only one mismatch out of 451 amino acids. An additional group of 15 large symptomless Brugmansia plants, located approximately 6 m from the five symptomatic plants, were also tested by RT-PCR and found to be positive. These 15 plants were of a different but also unknown species of Brugmansia. In conclusion, analysis of symptomatic Brugmansia from a Canadian collection by transfer of disease to herbaceous indicators, EM, RT-PCR, and genomic sequence comparisons, are consistent with the detection and identification of the potyvirus Colombian datura virus. To our knowledge, this is the first report of this viral pathogen in Canada. References: (1) S. Adkins et al. Phytopathology (Abstr.) 95(suppl.):S2, 2005. (2) C. R. Fry et al. J. Phytopathol. 152:200, 2004. (3) R. P. Kahn and R. Bartels. Phytopathology 58:58, 1968. (4) J. Schubert et al. J. Phytopathol. 154:343, 2006.

First Report of Pepino mosaic virus in Canada and the United States.

During the winter of 2000, tomatoes (Lycopersicon esculentum) with a bright yellow leaf mosaic were observed in a commercial greenhouse in southern Ontario, Canada. Examination of leaf extracts, using leaf dips and immunosorbent absorption electron microscopy (ISEM), showed flexuous rods consistent with the potexvirus group. Polyclonal antibodies raised against the original Peruvian Pepino mosaic virus (PepMV) isolate (1) and commercial antibodies obtained from Deutsche Sammlung von Mikro-organismen und Zellkulturen (DSMZ), GmbH, Braunsweig, Germany, and Plant Research International (PRI), Wageningen, the Netherlands, were used in ISEM. Leaves tested positive in double-antibody sandwich-enzyme-linked immunosorbent assay (ELISA) with antibodies from DSMZ and PRI. A triple-antibody sandwich-ELISA obtained from Adgen Ltd. (Nellies Gate, UK) gave similar results. Potato virus X did not react with PepMV antiserum in ELISA. Positive PepMV ELISA controls were a U.K. and a Dutch isolate supplied by R. Mumford and R. A. A. van Vlugt, respectively, and DSMZ. Using primers generated from a sequence of the RNA polymerase region of a U.K. PepMV isolate (R. Mumford, unpublished data), a reverse transcription-polymerase chain reaction test showed the expected 312-bp amplicon for the Canadian, Dutch, and U.K. isolates. The primer sequences used were forward 5' CTA TTA CAA CTC CGG AAG CCA 3' and reverse 5' TGG TCT GGC CAG GCT TTG AC 3'. The three isolates were maintained in tomato cv. Bush Beefsteak. When mechanically inoculated on L. esculentum cv. Rapsodie, the Canadian isolate caused a bright yellow mosaic in 1 to 2 weeks, while the two European isolates caused a faint yellow mosaic and mild puckering of the leaves. When mechanically inoculated on 17 indicator plants, the Canadian isolate had a host range similar to the U.K. isolate. The most striking difference in symptoms occurred in L. pimpinellifolium, in which the Canadian isolate caused a yellow mosaic, the Dutch isolate caused no symptoms, and the U.K. isolate caused a marked puckering of the leaves, suggesting virus strain differences among the isolates. Tomato fruits originating from the United States were collected during border inspections by the Canadian Food Inspection Agency and tested for PepMV by ELISA with antisera from DSMZ. PepMV was not detected in 7 samples from California, but was detected in 6 of 12 samples from Colorado, 6 of 7 samples from Arizona, and 1 of 5 samples from Texas. PepMV was originally isolated from pepino (Solanum muricatum) in Peru in 1980 (1) and subsequently from tomato in the Netherlands in 1999 (2). To our knowledge, this is the first report of PepMV in North America. References: (1) R. Jones et al. Ann. Appl. Biol. 94:61, 1980. (2) R. A. A. van Vlugt et al. Plant Dis. 84:103, 2000.

Electron Microscopic Detection of Novel, Coiled Viruslike Particles Associated with Graft-Inoculation of Prunus Species.

Coiled, viruslike particles (spirions) were detected by electron microscopic examination of crude extracts from flowers, leaves, and/or roots of infected Prunus avium, P. mume, and P. serrulata. The particles were observed in ultrathin sections of lower epidermis, palisade, and spongy mesophyll cells of leaves of P. avium and P. mume. Spring (March and April) appears to be optimal for detection of the particles in both screenhouse and field-grown plants. The particles were successfully graft-transmitted to P. armeniaca (cvs. Luizet and Tilton), P. avium (cvs. Bing, F12/1, Mazzard, and Sam), P. mahaleb, and P. persica (cv. Elberta). Individual spirions measured 132 × 34 nm. The particles appear to be coiled forms of a filamentous virus. Filaments extending from some coiled particles were approximately 13 nm wide, with striations at a pitch of 3.24 nm. No disease symptoms or cytopathological abnormalities were associated with the presence of the particles in the Prunus species studied. The particles were not detected in virus-free control plants.

Improved staining boxes for fast, uniform staining of ultrathin sections on grids.

A standard LKB (LKB-Produkter Ab. S-161, 25 Brommma 1, Sweden) grid storage box is converted into several grid staining boxes by sawing the body of the box into segments along rows of its grid storage cavities. The staining boxes can be cut out to any required size or shape. The polymethyacrylate storage box cover is discarded. Covers for the staining boxes are cut from thin sheet vinyl, which is more chemically resistant than polymethyacrylate. Corresponding 2 mm diameter holes are drilled through the vinyl covers and the bottoms of the grid storage cavities of the staining boxes to convert the storage cavities into staining chambers. For staining, the covers are tied to the boxes with sewing thread and the assembled units are put into vials. The separate staining chambers prevent intermingling of and mechanical damage to grids during the staining procedure. Ultrathin sections are more cleanly and uniformly stained in bulk by the use of these staining boxes than they are when stained individually by a standard method.