Development of Stable Infectious cDNA Clones of Tomato Black Ring Virus Tagged with Green Fluorescent Protein.

Tomato black ring virus (TBRV) is a member of the Nepovirus genus in the Secoviridae family, which infects a wide range of important crop species worldwide. In this work, we constructed four cDNA infectious clones of the TBRV tagged with the green fluorescent protein (TBRV-GFP), which varied in (i) the length of the sequences flanking the GFP insert, (ii) the position of the GFP insert within the RNA2 polyprotein, and (iii) the addition of a self-cutting 2A protein. The presence of the GFP coding sequence in infected plants was verified by RT-PCR, while the infectivity and stability of the constructs were verified by mechanical inoculation of the host plants. The systemic spread of TBRV-GFP within plants was observed under UV light at a macroscopic level, monitoring GFP-derived fluorescence in leaves, and at a microscopic level using confocal microscopy. The obtained clones are a valuable tool for future studies of TBRV-host interactions, virus biology, and the long-term monitoring of its distribution in infected plants.

Dicer-Like Protein 4 and RNA-Dependent RNA Polymerase 6 Are Involved in Tomato Torrado Virus Pathogenesis in Nicotiana benthamiana.

Tomato torrado virus (ToTV) is a type member of the Torradovirus genus in the Secoviridae family known to cause severe necrosis in susceptible tomato varieties. ToTV also infects other Solanaceae plants, including Nicotiana benthamiana, where it induces distinctive disease symptoms: plant growth drop with the emergence of spoon-like malformed systemic leaves. Virus-induced post-transcriptional gene silencing (PTGS) is significant among plant defense mechanisms activated upon virus invasion. The PTGS, however, can be counteracted by suppressors of RNA silencing commonly found in viruses, which efficiently disrupt the antiviral defense of their host. Here, we addressed the question of PTGS antiviral activity and its suppression in N. benthamiana during ToTV infection-a phenomenon not described for any representative from the Torradovirus genus so far. First, we showed that neither the Vp26-a necrosis-inducing pathogenicity determinant of ToTV-nor other structural viral proteins limited the locally induced PTGS similar to p19, a well-characterized potent suppressor of RNA silencing of tombusviruses. Moreover, by employing wild-type and transgenic lines of N. benthamiana with suppressed Dicer-like 2 (DCL2), Dicer-like 4 (DCL4), Argonaute 2 and RNA-dependent RNA polymerase 6 (RDR6) proteins, we proved their involvement in anti-ToTV defense. Additionally, we identified DCL4 as the major processor of ToTV-derived siRNA. More importantly, our results indicate the essential role of the Suppressor of Gene Silencing 3 (SGS3)/RDR6 pathway in anti-ToTV defense. Finally, we conclude that ToTV might not require a potent RNA silencing suppressor during infection of the model plant N. benthamiana.

A Novel Distinct Genetic Variant of Tomato Torrado Virus with Substantially Shorter RNA1-Specific 3'Untranslated Region (3'UTR).

Tomato torrado virus (ToTV) induces severe systemic necrosis in Solanum lycopersicum. This work aimed at describing the genetic variability of necrosis-inducing ToTV-Wal'17 collected in 2017, derived from the ToTV-Wal'03 after long-term passages in plants. Sequence analyses of the ToTV-Wal'17 indicated twenty-eight single nucleotide substitutions in coding sequence of both RNAs, twelve of which resulted in amino acid changes in viral polyproteins. Moreover the sequencing data revealed that the 3'UTR of ToTV-Wal'17 RNA1 was 394 nts shorter in comparison to Wal'03. The performed sequence analyses revealed that 3'UTR of RNA1 of ToTV-Wal'17 is the most divergent across all previously described European isolates.

Development of a New Tomato Torrado Virus-Based Vector Tagged with GFP for Monitoring Virus Movement in Plants.

Green fluorescent protein (GFP)-tagged viruses are basic research tools widely applied in studies concerning molecular determinants of disease during virus infection. Here, we described a new generation of genetically stable infectious clones of tomato torrado virus isolate Kra (ToTVpJL-Kra) that could infect Nicotiana benthamiana and Solanum lycopersicum. Importantly, a modified variant of the viral RNA2-with inserted sGFP (forming, together with virus RNA1, into ToTVpJL-KraGFP)-was engineered as well. RNA2 of ToTVpJL-KraGFP was modified by introducing an additional open reading frame (ORF) of sGFP flanked with an amino acid-coding sequence corresponding to the putative virus protease recognition site. Our further analysis revealed that sGFP-tagged ToTV-Kra was successfully passaged by mechanical inoculation and spread systemically in plants. Therefore, the clone might be applied in studying the in vivo cellular, tissue, and organ-level localization of ToTV during infection. By performing whole-plant imaging, followed by fluorescence and confocal microscopy, the presence of the ToTVpJL-KraGFP-derived fluorescence signal was confirmed in infected plants. All this information was verified by sGFP-specific immunoprecipitation and western blot analysis. The molecular biology of the torradovirus-plant interaction is still poorly characterized; therefore, the results obtained here opened up new possibilities for further research. The application of sGFP-tagged virus infectious clones and their development method can be used for analyzing plant-virus interactions in a wide context of plant pathology.

Recombination-based generation of the agroinfectious clones of Peanut stunt virus.

Full-length cDNA clones of Peanut stunt virus strain P (PSV-P) were constructed and introduced into Nicotiana benthamiana plants via Agrobacterium tumefaciens. The cDNA fragments corresponding to three PSV genomic RNAs and satellite RNA were cloned into pGreen binary vector between Cauliflower mosaic virus (CaMV) 35S promoter and nopaline synthase (NOS) terminator employing seamless recombinational cloning system. The plasmids were delivered into A. tumefaciens, followed by infiltration of hosts plants. The typical symptoms on systemic leaves of infected plants similar to those of wild-type PSV-P were observed. The presence of the virus was confirmed by means of RT-PCR and Western blotting. Re-inoculation to N. benthamiana, Phaseolus vulgaris, and Pisum sativum resulted in analogous results. Generation of infectious clones of PSV-P enables studies on virus-host interaction as well as revealing viral genes functions.

The N-terminal fragment of the tomato torrado virus RNA1-encoded polyprotein induces a hypersensitive response (HR)-like reaction in Nicotiana benthamiana.

The hypersensitive response (HR) is a defence reaction observed during incompatible plant-pathogen interactions in plants infected with a wide range of fungi, bacteria and viruses. Here, we show that an N-terminal polyprotein fragment encoded by tomato torrado virus RNA1, located between the first ATG codon and the protease cofactor (ProCo) motif, induces an HR-like reaction in Nicotiana benthamiana. Agrobacterium tumefaciens-mediated transient expression of the first 105 amino acids (the calculated molecular weight of the fragment was ca. 11.33 kDa, hereafter refered to as the 11K domain) from ToTV RNA1 induced an HR-like phenotype in infiltrated leaves. To investigate whether the 11K domain could influence the virulence and pathogenicity of a recombinant virus, we created a potato virus X (PVX) with the 11K coding sequence inserted under a duplicated coat protein promoter. We found that 11K substantially increased the virulence of the recombinant virus. Disease phenotype induced in N. benthamiana by PVX-11K was characterized by strong local and systemic necrosis. This was not observed when the 11K domain was expressed from PVX in an antisense orientation. Further analyses revealed that the 11K domain could not suppress posttranscriptional gene silencing (PTGS) of green fluorescent protein (GFP) in the N. benthamiana 16c line. In silico analysis of the predicted secondary structure of the 11K domain indicated the presence of two putative helices that are highly conserved in tomato-infecting representatives of the genus Torradovirus.

A single amino acid substitution in movement protein of tomato torrado virus influences ToTV infectivity in Solanum lycopersicum.

Tomato torrado virus (ToTV), which is a tomato-infecting member of the genus Torradovirus, induces severe systemic necrosis in Solanum lycopersicum cv. Beta Lux as well as leaf malformation and chlorosis in Nicotiana benthamiana. To date, neither the tomato gene conferring resistance to the pathogen nor the ToTV-encoded necrosis determinant have been characterized. We herein revealed that the phenylalanine 210 residue in the movement protein domain encoded by ToTV RNA2 is a necrosis-inducing pathogenicity determinant during tomato infection. Using a ToTV infectious RNA2 clone, we performed site-directed mutagenesis of the phenylalanine 210 residue, confirming its importance during ToTV infection and symptom manifestation in S. lycopersicum cv. Beta Lux, but not in N. benthamiana.

Effect of temperature on the pathogenesis, accumulation of viral and satellite RNAs and on plant proteome in peanut stunt virus and satellite RNA-infected plants.

Temperature is an important environmental factor influencing plant development in natural and diseased conditions. The growth rate of plants grown at C27°C is more rapid than for plants grown at 21°C. Thus, temperature affects the rate of pathogenesis progression in individual plants. We have analyzed the effect of temperature conditions (either 21°C or 27°C during the day) on the accumulation rate of the virus and satellite RNA (satRNA) in Nicotiana benthamiana plants infected by peanut stunt virus (PSV) with and without its satRNA, at four time points. In addition, we extracted proteins from PSV and PSV plus satRNA-infected plants harvested at 21 dpi, when disease symptoms began to appear on plants grown at 21°C and were well developed on those grown at 27°C, to assess the proteome profile in infected plants compared to mock-inoculated plants grown at these two temperatures, using 2D-gel electrophoresis and mass spectrometry approaches. The accumulation rate of the viral RNAs and satRNA was more rapid at 27°C at the beginning of the infection and then rapidly decreased in PSV-infected plants. At 21 dpi, PSV and satRNA accumulation was higher at 21°C and had a tendency to increase further. In all studied plants grown at 27°C, we observed a significant drop in the identified proteins participating in photosynthesis and carbohydrate metabolism at the proteome level, in comparison to plants maintained at 21°C. On the other hand, the proteins involved in protein metabolic processes were all more abundant in plants grown at 27°C. This was especially evident when PSV-infected plants were analyzed, where increase in abundance of proteins involved in protein synthesis, degradation, and folding was revealed. In mock-inoculated and PSV-infected plants we found an increase in abundance of the majority of stress-related differently-regulated proteins and those associated with protein metabolism. In contrast, in PSV plus satRNA-infected plants the shift in the temperature barely increased the level of stress-related proteins.

Construction of infectious clones of tomato torrado virus and their delivery by agroinfiltration.

The first biologically active infectious clones of tomato torrado virus (ToTV) were generated and delivered into Nicotiana benthamiana and Solanum lycopersicum plants via Agrobacterium tumefaciens. The engineered constructs consisted of PCR-amplified complementary DNAs derived from the ToTV RNA1 and RNA2 components, individually inserted into an engineered pGreen binary vector between the CaMV 35S promoter and nopaline synthase terminator. These constructs were introduced into the plant hosts by means of A. tumefaciens-mediated infiltration. In the presence of the progeny virus, typical symptoms of ToTV infection developed in N. benthamiana and S. lycopersicum. Moreover, the virus was sap-transmissible when isolated from agroinfiltrated plants and induced symptoms similar to those caused by the wild-type virus. The presence of viral particles and viral genetic material was confirmed by electron microscopy and re-inoculation to S. lycopersicum and N. benthamiana, as well as by reverse transcription polymerase chain reaction and high-resolution melt analysis.

Genetic variability within the Polish tomato torrado virus Kra isolate caused by deletions in the 3'-untranslated region of genomic RNA1.

Tomato torrado virus (ToTV) is in the genus Torradovirus in the family Secoviridae. ToTV contains a single-stranded, positive-sense, bipartite RNA genome encapsidated in icosahedral particles. It is a serious tomato pathogen causing significant crop reductions. Its occurrence has been reported from many countries worldwide. However, the state of knowledge of ToTV epidemiology, sequences and phylogeny is still rather poor. In this study we found that the Polish ToTV isolates are characterized by significant genetic variability of the 3'-untranslated region (UTR) of RNA1. The high resolution melting real-time PCR approach showed the presence of genetic variants within Polish ToTV isolates purified from Nicotiana benthamiana. Further sequencing of Kra ToTV revealed five genetic variants of RNA1 within the isolate differing in the 3'-untranslated region length resulting from deletions ranging from 6 to 163 nucleotides. In light of the published studies, the genetic variability of ToTV associated with large deletions within an isolate may not necessarily be rare and may influence the virus evolution and adaptation.

Assessment of reference gene stability influenced by extremely divergent disease symptoms in Solanum lycopersicum L.

Tomato (Solanum lycopersicum L.) is one of the most important vegetables of great worldwide economic value. The scientific importance of the vegetable results from the fact that the genome of S. lycopersicum has been sequenced. This allows researchers to study fundamental mechanisms playing an essential role during tomato development and response to environmental factors contributing significantly to cell metabolism alterations. Parallel with the development of contemporary genetics and the constant increase in sequencing data, progress has to be aligned with improvement of experimental methods used for studying genes functions and gene expression levels, of which the quantitative polymerase chain reaction (qPCR) is still the most reliable. As well as with other nucleic acid-based methods used for comparison of the abundance of specific RNAs, the RT-qPCR data have to be normalised to the levels of RNAs represented stably in a cell. To achieve the goal, the so-called housekeeping genes (i.e., RNAs encoding, for instance, proteins playing an important role in the cell metabolism or structure maintenance), are used for normalisation of the target gene expression data. However, a number of studies have indicated the transcriptional instability of commonly used reference genes analysed in different situations or conditions; for instance, the origin of cells, tissue types, or environmental or other experimental conditions. The expression of ten common housekeeping genes of S. lycopersicum, namely EF1α, TUB, CAC, EXP, RPL8, GAPDH, TBP, ACT, SAND and 18S rRNA were examined during viral infections of tomato. Changes in the expression levels of the genes were estimated by comparison of the non-inoculated tomato plants with those infected with commonly known tomato viral pathogens, Tomato torrado virus, Cucumber mosaic virus, Tobacco mosaic virus and Pepino mosaic virus, inducing a diverse range of disease symptoms on the common host, ranging from mild leaves chlorosis to very severe stem necrosis. It is emphasised that despite the wide range of diverse disease symptoms it is concluded that ACT, CAC and EF1α could be used as the most suitable reference genes in studies of host-virus interactions in tomato.

How can plant virus satellite RNAs alter the effects of plant virus infection? A study of the changes in the Nicotiana benthamiana proteome after infection by peanut stunt virus in the presence or absence of its satellite RNA.

Peanut stunt virus (PSV), which belongs to the Cucumovirus genus, is a pathogen of legumes. Certain PSV strains associated with a satellite RNA (satRNA) modify the symptoms of infected plants and interfere with plant metabolism. We used PSV-P genomic transcripts (GTs) with and without PSV-P satRNA and a comparative proteomic 2D-DIGE/MS study to assess their effects on Nicotiana benthamiana infection. When the proteomes of the PSV-P genomic transcripts-infected (no satRNA present) and mock-inoculated plants were compared 29 differentially regulated proteins were found. When comparisons were made for plants infected with PSV-P-GT in the presence or absence of satRNA, and for mock-infected plants and those infected with the satRNA-associated PSV-P-GT, 40 and 60 such proteins, respectively, were found. The presence of satRNA mostly decreased the amounts of the affected host proteins. Proteins involved in photosynthesis and carbohydrate metabolism, for example ferredoxin-NADP-reductase and malate dehydrogenase, are among the identified affected proteins in all comparisons. Proteins involved in protein synthesis and degradation were also affected. Such proteins include chaperonin 60ß--whose abundance of the proteins changed for all comparisons--and aminopeptidase that is a satRNA- or PSV-P-GT/satRNA-responsive protein. Additionally, the levels of the stress-related proteins superoxide dismutase and acidic endochitinase Q increased in the PSV-P-GT- and PSV-P-GT/satRNA-infected plants. This study appears to be the first report on plant proteome changes in response to a satRNA presence during viral infection and, as such, may provide a reference for future studies concerning the influence of satRNAs during viral infections.

Analysis of two strains of Peanut stunt virus: satRNA-associated and satRNA free.

Peanut stunt virus (PSV) is a pathogen of legumes, vegetables, trees, and weeds occurring worldwide. The species is characterized by significant genetic variability. PSV strains are classified into four subgroups on the basis of their nucleotide sequence homology. Here, we are presenting two further, fully sequenced PSV strains-PSV-Ag and PSV-G, that could be considered as I subgroup representatives. However, their sequence homology with other typical I subgroups members, similarly as another strain-PSV-P, characterized by our group previously, is lower than 90%. This lead us to propose further subdivision of the I subgroup into IA, IB, and IC units, and to classify PSV-Ag and PSV-G strains to the last one. In this article, we are showing that identity level of PSV-Ag and PSV-G is very high and apart from the presence of satRNA in the first one, they differ only by a few nucleotides in their genomic RNAs. Nevertheless, symptoms they cause on host plants might differ significantly, just as the levels in infected plants. Effect of single amino acid changes between strains on the three-dimensional structure of viral proteins was analyzed. Differences occur mainly on the protein surfaces which can possibly affect protein-protein interaction in infected cells, which is discussed.

The nucleotide sequence of a Polish isolate of Tomato torrado virus.

A new virus was isolated from greenhouse tomato plants showing symptoms of leaf and apex necrosis in Wielkopolska province in Poland in 2003. The observed symptoms and the virus morphology resembled viruses previously reported in Spain called Tomato torrado virus (ToTV) and that in Mexico called Tomato marchitez virus (ToMarV). The complete genome of a Polish isolate Wal'03 was determined using RT-PCR amplification using oligonucleotide primers developed against the ToTV sequences deposited in Genbank, followed by cloning, sequencing, and comparison with the sequence of the type isolate. Phylogenetic analyses, performed on the basis of fragments of polyproteins sequences, established the relationship of Polish isolate Wal'03 with Spanish ToTV and Mexican ToMarV, as well as with other viruses from Sequivirus, Sadwavirus, and Cheravirus genera, reported to be the most similar to the new tomato viruses. Wal'03 genome strands has the same organization and very high homology with the ToTV type isolate, showing only some nucleotide and deduced amino acid changes, in contrast to ToMarV, which was significantly different. The phylogenetic tree clustered aforementioned viruses to the same group, indicating that they have a common origin.