Oligonucleotide microarray-based detection and genotyping of Plum pox virus

Plum pox virus (PPV) is the most damaging viral pathogen of stone fruits. The detection and identification of its strains are therefore of critical importance to plant quarantine and certification programs. Existing methods to screen strains of PPV suffer from significant limitations such as the simultaneous detection and genotyping of several strains of PPV in samples infected with different isolates of the virus. A genomic strategy for PPV screening based on the viral nucleotide sequence was developed to enable the detection and genotyping of the virus from infected plant tissue or biological samples. The basis of this approach is a long 70-mer oligonucleotide DNA microarray capable of simultaneously detecting and genotyping PPV strains. Several 70-mer oligonucleotide probes were specific for the detection and genotyping of individual PPV isolates to their strains. Other probes were specific for the detection and identification of two or three PPV strains. One probe (universal), derived from the genome highly conserved 3' non-translated region, detected all individual strains of PPV. This universal PPV probe, combined with probes specific for each known strain, could be used for new PPV strain discovery. Finally, indirect fluorescent labeling of cDNA with cyanine after cDNA synthesis enhanced the sensitivity of the virus detection without the use of the PCR amplification step. The PPV microarray detected and identified efficiently the PPV strains in PPV-infected peach, apricot and Nicotiana benthamiana leaves. This PPV detection method is versatile, and enables the simultaneous detection of plant pathogens.     

Efficiency of inoculation of peach GF305 seedlings with Plum pox virus by different methods

Peach GF305 is frequently used as rootstock in experiments to evaluate the resistance of different species of Prunus to Plum pox virus (PPV) because of its extreme susceptibility. However, transmission of PPV in Prunus species is sometimes problematic due to its low concentration or uneven distribution in these species. To determine the most effective way of transmitting the virus, different infection methods (by aphids, grafting, mechanical infection and injection) were tested using Dideron PPV isolates. The most effective method was the grafting of herbaceous material with inoculum derived from similar herbaceous material. Infection by aphids was more laborious and less effective than grafting, showing many disadvantages. Neither mechanical infection nor injection transmitted the virus.     

Detection and differentiation of Plum pox virus using real-time multiplex PCR with SYBR Green and melting curve analysis: a rapid method for strain typing

A real-time multiplex PCR procedure with melting curve analysis, using the green fluorescence dye SYBR Green I, was developed for rapid and reliable identification of Plum pox virus (PPV) isolates of strains D and M. Members of the different strains were identified by their distinctive melting temperatures (T(m)s); 84.3-84.43 degrees C for D isolates, and 85.34-86.11 degrees C for M isolates. The associated amplicon sizes were 114 and 380 bp, respectively. The procedure was used for detection and identification of PPV in both herbaceous and woody hosts. The Tm for members of a particular strain was very similar, with a host effect that did not hinder strain identification. Universal primers included in the study detected all isolates of PPV tested, amplifying a 74 bp fragment. The Tm of this fragment varied from 80.12 to 81.52 degrees C and may have supplementary value for PPV identification. SYBR Green-based detection was compared to detection using a hybridization LUX fluorogenic primer. Better resolution of the melting peaks was observed with SYBR Green I, than with the LUX primers, hence strain identification with SYBR Green I was more reliable. This is a simple approach to PPV strain identification with the relatively inexpensive dye SYBR Green I, and eliminates any need for electrophoretic analysis of amplicons or RFLP patterns using ethidium bromide.     

Evaluation of the genetic diversity of Plum pox virus in a single plum tree

Recent research has shown that Coronavirus (CoV) replication depends on active immunophilin pathways. Here we demonstrate that the drug FK506 (Tacrolimus) inhibited strongly the growth of human coronaviruses SARS-CoV, HCoV-NL63 and HCoV-229E at low, non-cytotoxic concentrations in cell culture. As shown by plaque titration, qPCR, Luciferase- and green fluorescent protein (GFP) reporter gene expression, replication was diminished by several orders of magnitude. Knockdown of the cellular FK506-binding proteins FKBP1A and FKBP1B in CaCo2 cells prevented replication of HCoV-NL63, suggesting the requirement of these members of the immunophilin family for virus growth.     

A sensitive method for the detection of foot and mouth disease virus by in situ hybridisation using biotin-labelled oligodeoxynucleotides and tyramide signal amplification

An in situ hybridisation technique, based on oligodeoxynucleotide probes and tyramide signal amplification, is described for the detection of foot and mouth disease virus RNA in infected cells. Biotinylated oligodeoxynucleotide probes, with and without tyramide signal amplification, were compared. The tyramide signal amplification detection enhances by at least 100-fold the sensitivity of in situ hybridisation.     

Differential RNAi responses of Nicotiana benthamiana individuals transformed with a hairpin-inducing construct during Plum pox virus challenge

Gene silencing and large-scale small RNA analysis can be used to develop RNA interference (RNAi)-based resistance strategies for Plum pox virus (PPV), a high impact disease of Prunus spp. In this study, a pPPViRNA hairpin-inducing vector harboring two silencing motif-rich regions of the PPV coat protein (CP) gene was evaluated in transgenic Nicotiana benthamiana (NB) plants. Wild-type NB plants infected with a chimeric PPV virus (PPV::GFP) exhibited affected leaves with mosaic chlorosis congruent to GFP fluorescence at 21 day post-inoculation; transgenic lines depicted a range of phenotypes from fully resistant to susceptible. ELISA values and GFP fluorescence intensities were used to select transgenic-resistant (TG-R) and transgenic-susceptible (TG-S) lines for further characterization of small interfering RNAs (siRNAs) by large-scale small RNA sequencing. In infected TG-S and untransformed (WT) plants, the observed siRNAs were nearly exclusively 21- and 22-nt siRNAs that targeted the whole PPV::GFP genome; 24-nt siRNAs were absent in these individuals. Challenged TG-R plants accumulated a full set of 21- to 24-nt siRNAs that were primarily associated with the selected motif-rich regions, indicating that a trans-acting siRNAs process prevented viral multiplication. BLAST analysis identified 13 common siRNA clusters targeting the CP gene. 21-nt siRNA sequences were associated with the 22-nt siRNAs and the scarce 23- and 24-nt molecules in TG-S plants and with most of the observed 22-, 23-, and 24-nt siRNAs in TG-R individuals. These results validate the use of a multi-hot spot silencing vector against PPV and elucidate the molecules by which hairpin-inducing vectors initiate RNAi in vivo.     

Loop-mediated isothermal amplification for rapid detection of Newcastle disease virus

We have evaluated a diagnostic system based on the loop-mediated isothermal amplification (LAMP) assay for the rapid, simple, and sensitive detection of Newcastle disease virus (NDV) directly from culture isolates as well as clinical samples. By using one set of specific primers targeting the fusion protein gene, the LAMP assay rapidly amplified the target gene within 2 h, requiring only a regular laboratory water bath or heat block for reaction. The results obtained from testing the genomes of 38 NDV strains, other different viruses, and clinical samples of experimentally infected chickens showed that LAMP was as sensitive and specific as nested PCR. All LAMP-positive samples were positive by nested PCR. The LAMP assay is faster than nested PCR, cost-effective, and easy to perform. Our results clearly demonstrate that the LAMP-based assay is a useful tool for the rapid and sensitive diagnosis of NDV infection.     

Localization of Plum pox virus in stem and petiole tissues of apricot cultivars by immuno-tissue printing

Localization of Plum pox virus (PPV) in stem and petiole tissues of four susceptible and four resistant apricot cultivars has been studied. Consecutive 1-mm spaced transverse sections were taken from the tissues and were printed onto nitrocellulose membrane in duplicate. For virus-specific detection, one series of prints was probed with an antibody to PPV coat and the density of stains was evaluated by light microscopy. Another series of prints was treated with a substrate but not with the antibody to reveal non-specific staining due to endogenous peroxidases. The virus was currently detected in all inoculated susceptible cultivars but only in one inoculated resistant cultivar (Harcot). In the stem tissues, the virus was localized in the pith and in the xylem. In the petiole tissues, it was localized in the epidermis and in cortical and medullae parenchyma. Non-specific staining was observed only in the stem sclerenchyma and in the petiole phloem.     

Nucleotide sequence analysis of Plum pox virus isolate W3174: evidence of a new strain

The nucleotide sequence of Plum pox virus (PPV) isolate W3174 was determined. The virus genome consists of 9788 nucleotides (nt), excluding the poly(A) tail at the 3′-terminus, with 5′- and 3′-untranslated regions (UTRs) of 146 and 219 nt, respectively. The deduced polyprotein consists of 3141 amino acid (aa) residues, with the coat protein region consisting of 993 nt (331 aa). In comparisons with PPV-D, -M, -EA and -C isolates, nucleotide identity levels ranged from 79 to 80% for the entire genome and from 78 to 79%, 78 to 81%, and 92 to 95% for the NIb, CP, and 3′-UTR regions, respectively. The majority of nucleotide substitutions in the NIb region of W3174 are silent, while substitutions in the CP region are not silent, giving aa identities of 89–91% and 79–81%, respectively. The HC-Pro region contains the KITC and PTK motifs, and the DAG motif is located at positions 12–14 of the deduced CP aa sequence, all associated with aphid transmission. Phylogenetic analysis based on the complete genome sequence, the NIb, CP, and 3′-UTR region were performed. PPV-W3174 consistently formed a distinct clade or group, when compared to members of all four recognized strains of PPV, indicating that it is genetically distinct. These results are consistent with serological and nucleic acid-based strain typing data and justify recognition of this isolate as representative of a new strain identified as PPV-W.     

Transfection of Arabidopsis protoplasts with a Plum pox virus (PPV) infectious clone for studying early molecular events associated with PPV infection

The development of novel strategies against plant viral diseases relies on a better understanding of molecular virus-host interactions. Here, we report an easy, efficient and reproducible protocol for Arabidopsis protoplast isolation and transfection to study the infection and replication of a potyvirus, Plum pox virus (PPV). Macerozyme and cellulose were used to release protoplasts from Arabidopsis leaf tissues, and polyethylene glycol-mediated DNA uptake was employed for transfection of a PPV infectious clone. Protoplast viability was monitored by fluorescein diacetate staining, and transfection efficiency was estimated by transient expression of the green fluorescent protein. The protocol allowed production of 95% viable mesophyll protoplasts and a successful transfection rate of 35%. The system was used further in a time-course experiment to investigate PPV viral RNA accumulation. It was found that 3 h post-transfection (hpt) in the transfected protoplasts viral RNA increased by about 150-fold and progressively accumulated to reach the maximum at 12 hpt. Viral RNA then decreased dramatically at 24 hpt reaching 40% of its peak level. Considering the availability of the whole genome microarrays, and other genomic resources of Arabidopsis, the synchronized single-cell (protoplast) infection system will be useful for elucidating early molecular events associated with PPV infection.