H. R. Pappu

Incidence and Relative Prevalence of Distinct Caulimoviruses (Genus Caulimovirus, Family Caulimoviridae) Associated with Dahlia Mosaic in Dahlia variabilis

Dahlia mosaic, caused by Dahlia mosaic virus (DMV), is one of the most important viral diseases of dahlia. Molecular characterization of DMV showed the association of two distinct caulimoviruses (DMV-D10, DMV-Portland) and a D10-like sequence variant (DMV-Holland) with the disease. Using primers specific to these two viruses and the sequence variant, a polymerase chain reaction-based assay was used to determine their relative incidence in several dahlia samples from the United States and the Netherlands. Testing was done on samples collected in 2005 and 2006 in the United States and in 2006 in the Netherlands. Results indicated the predominance of DMV-D10 over DMV-Portland and DMV-Holland in both the United States and the Netherlands. Using conserved regions of the viral genome, primers were designed and used to detect all three sequences. Results suggested that DMV-D10 is predominantly associated with dahlia mosaic, but diagnostics should also include testing for DMV-Portland and DMV-Holland.

Evaluation of acibenzolar-S-methyl-induced resistance against iris yellow spot tospovirus

Acibenzolar-S-Methyl (ASM) is a functional analog of salicylic acid (SA) that activates local and systemic acquired resistance (SAR) responses in plants against a wide variety of pathogens. Iris yellow spot virus (IYSV) is an economically important tospovirus of onion that causes severe economic losses to both bulb and seed crops. IYSV resistant onion cultivars are not available to date and there are limited control options. To explore the possibility of utilizing SAR as a control option, we first used two different hosts of IYSV, Datura stramonium and Nicotiana benthamiana, to study the ability of ASM in triggering SAR against IYSV infection. Quantitative descriptors based on both symptom expression and relative levels of IYSV nucleoprotein and viral small RNA were developed and used to determine the SAR in ASM- and buffer-treated plants. A significant reduction in virus levels in ASM-treated plants was noticed by ELISA and PCR. The level of SAR response was also assessed by measuring the IYSV lesion size and number on the inoculated leaves of ASM-treated plants. ASM-treated plants showed reduced symptoms compared to buffer-treated plants. This study could be useful in potentially developing novel SAR-based options for virus management.

The first complete genome sequences of two distinct European tomato spotted wilt virus isolates

Tomato spotted wilt virus (TSWV) represents a major constraint to the production of important vegetable and ornamental crops in several countries around the world, including those in Europe. In spite of their economic importance, European TSWV isolates have only been partially characterized, and a complete genome sequence has not been determined yet. In this study, we completed the whole genome sequence of two distinct TSWV isolates from Italy, p105 and p202/3WT. The sequences of the L and M segments of p105 and of the L segment of p202/3WT were determined using a combined approach of RT-PCR and small RNA (sRNAs) contig assembly. Phylogenetic analysis based on RNA-dependent RNA polymerase and GN/GC protein sequences grouped the two isolates in two different clades, showing that different evolutive lineages are present among Italian TSWV isolates. Analysis of possible recombination/reassortment events among our isolates and other available full-length genome TSWV sequences showed a likely reassortment event involving the L segment.

Identification and characterization of biologically distinct isolates of Iris yellow spot virus (genus Tospovirus, family Bunyaviridae), a serious pathogen of onion

Iris yellow spot virus (IYSV) causes an economically important disease in onion bulb and seed crops. While considerable information on the genetic diversity of the virus is available, little is known about the biological variability of the virus. Using two experimental hosts, Nicotiana benthamiana and Datura stramonium, IYSV from naturally infected onion fields was evaluated to determine the existence of biologically different isolates using the following criteria: ability to establish infection and become systemic, and the severity of the disease caused in inoculated plants. Additionally, the nucleocapsid gene of these biologically distinct isolates of IYSY was characterized at the molecular level.

Genomic characterization of pea enation mosaic virus-2 from the Pacific Northwestern USA

Pea enation mosaic virus (PEMV) infects several legume crops, including chickpea (Cicer arietinum), faba bean (Vicia faba), lentil (Lens culinaris) and pea (Pisum sativum). The virus caused yield losses of food legumes in the Pacific Northwestern US during 1983, 1987 and 1990 [1]. Our recent surveys of pea and alfalfa fields in the states of Washington and Idaho, USA, have shown the prevalence of PEMV on pea. PEMV consists of a large (RNA-1 or PEMV-1) and a small (RNA-2 or PEMV-2) single-stranded positive-sense RNA, which are encapsidated separately into distinct isometric particles [2]. PEMV-2 is one of the seven distinct virus species in the genus Umbravirus. The other species of this genus are Carrot mottle virus (CMoV), Carrot mottle mimic virus (CMoMV), Groundnut rosette virus (GRV), Lettuce speckles mottle virus (LSMV), Tobacco mottle virus (TMoV) and Tobacco bushy top virus (TBTV) [3]. Members of this group lack the coat protein (CP) gene in their genomes and depend on a helper virus for survival [4]. PEMV-2 in association with PEMV-1 (genus Enamovirus), form a symbiotic bipartite virus complex referred to as PEMV. It has been suggested that RNA-1 and RNA-2 are essential for PEMV infection [4, 5]. The RNA-1 (5706 nucleotides) encodes five major ORFs (1-5) that have nucleotide and amino acid sequence similarities with subgroup II luteoviruses [5]. While PEMV-1 provides the necessary encapsidation and vector-transmission abilities for PEMV-2, the latter provides PEMV-1 with long-distance movement and mechanical transmission functions. As part of an ongoing project to determine the genetic diversity of PEMV, we recently characterized the genome of PEMV-1 from the Pacific Northwest [6]. So far, there are only two complete genomic sequences of PEMV-2 in GenBank (NC_003853 and AY714213). To better understand sequence diversity of PEMV-2, the genome structure and organization of two PEMV isolates, one from Idaho (PEMV-2-ID) and one from Washington (PEMV-2-WA), were determined in this study. The PEMV-2 genome (*4.2 kbp), like that of other umbraviruses, predominantly consists of four ORFs (1-4), which perform diverse functions [4, 7, 8]. RNA-2 lacks a polyadenylation signal at its 30 end and contains a large 50 genome-linked protein [9]. ORF-1, at the 50 end of the virus genome, initiates after a short, 20-nt non-coding region (NCR) and encodes a putative 33-kDa protein of unknown function. ORF-2 overlaps with ORF-1 at its 30 end and potentially encodes a protein of 65 kDa through a frameshift mechanism. ORF-2 contains sequence motifs characteristic of a viral RNA-dependent RNA-polymerase (RdRp). The presence of a polymerase cassette in RNA-2 also reveals its independent replicative capabilities. Also, due to the presence of an octanucleotide frameshift signal ‘‘GGATTTTT’’ immediately upstream of the stop codon of ORF-1, ORF-1, along with ORF-2, is expressed by a -1 frameshift mechanism as a minor translation product of 97 kDa [4]. ORFs 3 and 4 in the genome occur after a nonThe sequences described here were deposited in the GenBank database with the following accession numbers: JF713435 for PEMV2-WA and JF713436 for PEMV-2-ID.

Molecular characterization of pea enation mosaic virus and bean leafroll virus from the Pacific Northwest, USA

The family Luteoviridae consists of eight viruses assigned to three different genera, Luteovirus, Polerovirus and Enamovirus. The complete genomic sequences of pea enation mosaic virus (genus Enamovirus) and bean leafroll virus (genus Luteovirus) from the Pacific Northwest, USA, were determined. Annotation, sequence comparisons, and phylogenetic analysis of selected genes together with those of known polero- and enamoviruses were conducted.

Identification and molecular characterization of a new potyvirus infecting Triteleia species.

Plants of Triteleia hyacinthina, Triteleia ixioides Starlight, and Triteleia laxa Corina with severe mosaic and yellow vein-banding were found to be infected with a potyvirus. The 3′-terminal region of the virus was amplified by RT-PCR from total RNA using a potyvirus-specific degenerate primer (poty5P: 5′ GGN AAY AAY AGY GGN CAR CC 3′) and an oligo-dTprimer. The sequence generated included the 3′-NIb protein coding region (680 nucleotides), the entire coat protein coding region (840 nucleotides), and 3’-untranslated region (UTR) (253 nucleotides). Amino acid identity of the whole CP between the triteleia virus and potyvirus member ranged from 54% Apium virus Y (ApVY) to 67% Auraujia mosaic virus (ArjMV) and Twisted-stalk chlorotic streak virus (TSCSV) and the core ranged from 59% (ApVY) to 75% (ArjMV). The 3-UTR showed no significant homology with other known potyviruses. Phylogenetic relationships suggest this triteleia virus is a new member of the Potyvirus genus and the name of “Triteleia mosaic virus” (TriMV) is proposed. This is the first report of a potyvirus infecting triteleia.

Genomic characterization of pararetroviral sequences in wild Dahlia spp. in natural habitats

The genome structure and organization of endogenous caulimovirus sequences from dahlia (Dahlia spp), dahlia mosaic virus (DMV)-D10 from three wild species, D. coccinea (D10-DC), D. sherffii (D10-DS) and D. tenuicaulis (D10-DT), were determined and compared to those from cultivated species of dahlia, D. variabilis (DvEPRS). The complete ca. 7-kb dsDNA genomes of D10-DC, D10-DS, and D10-DT had a structure and organization typical of a caulimovirus and shared 89.3 to 96.6% amino acid sequence identity in various open reading frames (ORF) when compared to DvEPRS. The absence of the aphid transmission factor and the truncated coat protein fused with the reverse transcriptase ORF were common among these DMV-D10 isolates from wild Dahlia species.

Molecular characterization of allium virus X, a new potexvirus in the family Alphaflexiviridae, infecting ornamental allium.

AbtractA new potexvirus affecting ornamental allium spp in the Netherlands was identified and characterized at the molecular level. The virus had a single-stranded RNA genome of 7100 bp (excluding the 18 bp poly A tail). The genome organization was found to be typical of members of the genus Potexvirus and consisted of five open reading frames (ORF). Nucleotide and amino acid sequence comparisons with those of known potexvirus members showed that this virus is related to Hosta virus X and Hydrangea ringspot virus. Sequence similarities and phylogenetic relationships suggested that the allium virus is a new and distinct species in the genus Potexvirus and the name, Allium virus X (AlVX) is proposed.

Expression of endogenous para-retroviral genes and molecular analysis of the integration events in its plant host Dahlia variabilis

The dahlia (Dahlia variabilis) genome contains an endogenous pararetrovirus sequence (EPRS) tentatively designated as DvEPRS. The DvEPRS shares genome structure and organization that is typical of members of the Caulimovirus genus. Studies were carried out to better understand the nature of this integration and to determine the gene expression of this DvEPRS. Genomic Southern hybridization showed multiple and random integration events of the DvEPRS in the dahlia genome. To investigate the presence of DvEPRS transcripts, RT-PCR was done on DNase-treated total RNA from DvEPRS-infected dahlia plants. Results showed the expression of open reading frames I, V, and VI. Direct PCR from sap extracts produced more intense DNA amplicons of Dahlia mosaic virus and Dahlia common mosaic virus which are believed to exist as typical episomal caulimoviruses, whereas significantly less intense amplicon was seen in case of DvEPRS in comparison with internal transcribed spacer region of dahlias amplicon. The DvEPRS in wild and cultivated species of Dahlia offer a model system to study the molecular events underlying the ecology, evolution and spread of DvEPRS within natural and managed ecosystems and the factors affecting integration of these EPRS in the plant genome.