Identification of divergent isolates of cherry latent virus 1 in Greek sweet cherry orchards.

In this study, samples collected from eight sweet cherry trees in northern Greece were analyzed by high-throughput sequencing for the presence of viruses. Bioinformatic analysis revealed the presence of divergent isolates of cherry latent virus 1 (CLV-1), a recently identified trichovirus in a sweet cherry accession imported into the USA from the Republic of Georgia. The complete genome sequences of seven CLV-1 isolates were determined, and phylogenetic analysis indicated that they belonged to a separate clade from the previously characterized Georgian isolate. A small-scale survey confirmed the presence of CLV-1 in 47 out of 151 sweet cherry samples tested, and partial sequencing of 15 isolates showed a high degree of nucleotide sequence similarity among them.

Identification and Sequence Analysis of a Novel Ilarvirus Infecting Sweet Cherry.

In the present study, we utilized high throughput and Sanger sequencing to determine the complete nucleotide sequence of a putative new ilarvirus species infecting sweet cherry, tentatively named prunus virus I (PrVI). The genome of PrVI is comprised of three RNA segments of 3474 nt (RNA1), 2911 nt (RNA2), and 2231 nt (RNA3) and features conserved motifs representative of the genus Ilarvirus. BlastN analysis revealed 68.1-71.9% nt identity of PrVI with strawberry necrotic shock virus (SNSV). In subsequent phylogenetic analysis, PrVI was grouped together with SNSV and blackberry chlorotic ringspot virus (BCRV), both members of subgroup 1 of ilarviruses. In addition, mini-scale surveys in stone fruit orchards revealed the presence of PrVI in a limited number of sweet cherries and in one peach tree. Overall, our data suggest that PrVI is a novel species of the genus Ilarvirus and it consists the fifth member of the genus that is currently known to infect Prunus spp.

Interplay of Cucurbit Yellow Stunting Disorder Virus With Cucurbit Chlorotic Yellows Virus and Transmission Dynamics by Bemisia tabaci MED.

Cucurbit chlorotic yellows virus (CCYV) and cucurbit yellow stunting disorder virus (CYSDV) are two closely related criniviruses that often coinfect cucurbits and are associated with cucurbit yellows disease. Both viruses are distributed worldwide and are transmitted in a semipersistent manner by the whitefly vectors Bemisia tabaci MED or MEAM1. The major goal of this study was to provide insight into the interaction of CCYV and CYSDV in cucumber and to study the effect on transmission by B. tabaci MED. The titers of both viruses were estimated in single- and dually infected cucumber plants via reverse transcription PCR assays. In mixed infections, the accumulation of both viruses was significantly decreased. When B. tabaci MED adults were placed on cucumber infected with both viruses, their simultaneous transmission efficiency was significantly higher, whereas transmission efficiency of each individual virus was low. Moreover, nonviruliferous whiteflies preferentially settled on crinivirus-infected cucumber plants, whereas viruliferous whiteflies were attracted by healthy cucumber plants. Finally, the titer of both viruses was calculated in five commercial cucumber hybrids, followed by subsequent transmission experiments. Our results show that although the titers of CYSDV and CCYV were significantly lower in mixed infections in cucumbers, their simultaneous transmission increased.

Cucurbit chlorotic yellows virus p22 is a suppressor of local RNA silencing.

RNA silencing is a major antiviral mechanism in plants, which is counteracted by virus-encoded proteins with silencing suppression activity. ORFs encoding putative silencing suppressor proteins that share no structural or sequence homology have been identified in the genomes of four criniviruses. In this study, we investigated the RNA silencing suppression activity of several proteins encoded by the RNA1 (RdRp, p22) and RNA2 (CP, CPm and p26) of cucurbit chlorotic yellows virus (CCYV) using co-agroinfiltration assays on Nicotiana benthamiana plants. Our results indicate that p22 is a suppressor of local RNA silencing that does not interfere with cell-to-cell movement of the RNA silencing signal or with systemic silencing. Furthermore, comparisons of the suppression activity of CCYV p22 with that of two other well-known crinivirus suppressors (CYSDV p25 and ToCV p22) revealed that CCYV p22 is a weaker suppressor of local RNA silencing than the other two proteins. Finally, a comparative sequence analysis of the p22 genes of seven Greek CCYV isolates was performed, revealing a high level of conservation. Taken together, our research advances our knowledge about plant-virus interactions of criniviruses, an emergent group of pathogens that threatens global agriculture.

Insights Into the Etiology of Polerovirus-Induced Pepper Yellows Disease.

The study of an emerging yellows disease of pepper crops (pepper yellows disease [PYD]) in Greece led to the identification of a polerovirus closely related to Pepper vein yellows virus (PeVYV). Recovery of its full genome sequence by next-generation sequencing of small interfering RNAs allowed its characterization as a new poleroviruses, which was provisionally named Pepper yellows virus (PeYV). Transmission experiments revealed its association with the disease. Sequence similarity and phylogenetic analysis highlighted the common ancestry of the three poleroviruses (PeVYV, PeYV, and Pepper yellow leaf curl virus [PYLCV]) currently reported to be associated with PYD, even though significant genetic differences were identified among them, especially in the C-terminal region of P5 and the 3' noncoding region. Most of the differences observed can be attributed to a modular type of evolution, which produces mosaic-like variants giving rise to these different poleroviruses Overall, similar to other polerovirus-related diseases, PYD is caused by at least three species (PeVYV, PeYV, and PYLCV) belonging to this group of closely related pepper-infecting viruses.