First report of saffron latent virus in Crocus sativus from Hungary.

In early April of 2018 we sampled asymptomatic autumn flowering Crocus plants (Fig. S1.) in a private collection in Hajdú-Bihar county, Hungary. From each species (Cr. kotschyanus subsp. kotschyanus, Cr. sativus, Cr. speciosus) 200 mg leaf sample was collected from 5 neighboring shoot, which were treated as one sample. ELISA tests were carried out in duplicates using potyvirus-specific MAb PTY1 antibodies (Jordan and Hammond 1991) on the samples (Agdia, Elkhart, IN, USA). A sample was considered positive if the absorbance was at least three times greater than that of the negative control. Only one sample tested positive; the absorbance values of Cr. sativus leaves were 0.013 and 0.014, while the negative controls were 0.002 and 0.003, respectively. The samples were further tested by RT-PCR for potyviruses (Salamon and Palkovics 2005), tomato spotted wilt virus (TSWV) (Nemes and Salánki 2020) and nepovirus subgroup A (Digiaro et al. 2007). Total nucleic acid was extracted with the phenol-chloroform method of White and Kaper (1989), and reverse transcription was carried out with Maxima H Minus First Strand cDNA Synthesis Kit (Thermo Fisher Scientific Baltics UAB, Vilnius, Lithuania) using random hexamer primer. The samples were negative for TSWV and nepovirus subgroup A, but a single PCR product of ~ 1700 nucleotide (nt) was amplified with potyvirus specific primers and cloned into pGEM®-T Easy vector (Promega, Madison, WI, USA). The 1726 nt long insert sequence, including the complete coat protein region was determined and deposited in the NCBI GenBank database (Accession No: OR425160). Digestion of the original PCR products with restriction enzyme SacI yielded only the predicted restriction fragments (364 / 1362 bp), indicating the presence of only a single potyvirus in the infected sample. BLASTn analysis of the CP cistron revealed the highest nt identities to saffron latent virus (SaLV) Iranian isolates (GenBank AccNo.: MN990394 - 85.44%, MN990415 - 85.39% and RefSeq: NC_036802 - 84.05%). For phylogenetic analyses MEGA11 (Tamura et al. 2021) was used. The resulting Maximum Likelihood tree (Fig. S2) showed that all Iranian SaLV isolates grouped together, while the Hungarian isolate is on an adjacent branch, separate from other virus species, and supported with 100% bootstrap values. From these results, it appears that the Hungarian isolate has been separated from the Iranian clade, and has evolved separately as a distinct lineage. We were unable to fulfill Koch's postulates as all available Crocus sativus plants were infected with SaLV. Latent potyvirus infection of Crocus species, by bean yellow mosaic virus (BYMV), iris mild mosaic virus (IMMV), iris severe mosaic virus (ISMV) and turnip mosaic virus (TuMV) has been reported by Grilli Caiola and Faoro (2011). SaLV was first reported from Iran (Parizad et al. 2017), but to our knowledge has never been reported from Europe or from any current EPPO member state. Since Crocus species can be asymptomatic virus reservoirs, it is important that any certification scheme for production should require laboratory tests to prove the health of the plants; or advise growers to keep possible high value susceptible crops such as breeding material and nuclear stocks at a distance from crocuses to mitigate virus transmission between stocks. It is also advisable to grow infected lots far from healthy stocks and protected wild hosts. To our knowledge, this is the first report of SaLV from Hungary and from Europe.

First report of meadow saffron breaking virus on wild Colchicum autumnale from a stricly protected Natura2000 site at a Hungarian National Park.

In mid-April of 2018 light green to greenish yellow linear stripes (Fig. S1.) were observed on the foliage of meadow saffron (Colchicum autumnale) plants - which are native to Hungary - at a strictly protected Natura2000 site maintained by the Duna-Ipoly National Park (DNPI). By autumn, during the flowering season, flower breaking symptoms (Fig. S2.) were noticed, which indicated possible viral infection. With the permit of the Government Office of Pest County and the DNPI, 200 mg leaf sample was collected from one symptomatic plant in spring 2021 and stored at -70 °C until further processing. At the time of the sampling about 2.5 % of the ~ 5000 meadow saffron were symptomatic. Multiplex RT-PCR testing of the sample and an asymptomatic C. autumnale plant for cucumber mosaic virus, tomato spotted wilt virus (Nemes and Salánki 2020) and Nepovirus subgroup-A (Digiaro et al. 2007) gave negative results. The asymptomatic plant also tested negative for potyviruses (Salamon and Palkovics 2005). The asymptomatic (healthy) C. autumnale plant was inoculated with leaf sap of the sample (0.02M Sörensen's phosphate buffer pH 7.2 + 2 % PVP-40 (m/v)) resulting in symptoms of flower breaking in autumn of 2021, and linear stripes on the foliage in spring 2022, identical to symptoms on the originally infected plant. ELISA tests were carried out on the source plants in duplicate using potyvirus-specific MAb PTY1 antibodies (Jordan and Hammond 1991) (Agdia, Elkhart, IN, USA). Absorbance values were 1.519 and 1.530, while the negative controls were 0.003 and 0.007, respectively indicating potyvirus infection of the sample. Molecular tests were carried out on the source and inoculated plant samples in 2022. Total nucleic acid was extracted with the modified CTAB protocol of Xu et al. (2004), and reverse transcription was carried out with Maxima H Minus First Strand cDNA Synthesis Kit (Thermo Fisher Scientific Baltics UAB, Vilnius, Lithuania) with poly T2 (5'-CGGGGATCCTCGAGAAGCTTTTTTTTTTTTTTTTT-3') primer (Salamon and Palkovics 2005). PCR amplification was carried out with poty7941 (5'-GGAATTCCCGCGGNAAYAAYAGYGGNCARCC-3') and poly T2 primers as described earlier (Salamon and Palkovics 2005). A PCR product of ~ 1.6 kb was obtained in each case (Fig. S3.), cloned into pGEM®-T Easy vector (Promega, Madison, WI, USA) and transformed into E. coli DH5α strain. The obtained 1642 nucleotide (nt) sequence encompassing the complete coat protein (CP) was determined (Accession No: OP057214). The virus sequence present in the source and inoculated plants shared 100% nt identity. EcoRV digestion of the PCR products yielded two restriction fragments (369/1273 bp), indicating the presence of a single potyvirus in the infected plant tissue (Fig. S3.). BLASTN analysis of the CP cistron revealed highest nt identity (93.91 %) to meadow saffron breaking virus (MSBV) isolate FR GenBank Acc. No.: AY388995. MSBV was first reported in the Alsace region of France at an INRA research station in cultivated meadow saffron plants showing similar symptoms and the disease reached 100% incidence within a year (Poutaraud et al. 2004). Potyviruses are transmitted mechanically and by aphids (Inoue-Nagata et al. 2022). The spread of MSBV could lead to the infection and decline of the population of Colchicum in protected ecosystems. To our knowledge, this is the first report of MSBV on wild meadow saffron plant from a strictly protected Natura2000 site at a Hungarian National Park.

Peanut stunt virus movement protein is the limiting factor in Capsicum annuum infection.

Cucumber mosaic virus (CMV) is one of the most devastating plant viruses, with more than 1,200 species of host plants. The host range and economic importance of peanut stunt virus (PSV) are mostly limited to legumes, despite the similar taxonomy and genome structure with CMV. Since no data are available on the background of the limited host range of PSV, RNA 3 recombinant and reassortant viruses were generated (C12P3, P12C3, C12CP3, C12PC3, C12PΔC3) to study their infection phenotype on a common host (Nicotiana benthamiana) and on a selective host (Capsicum annuum cv. Brody). The PSV movement protein (MP) was not able to function with the coat protein (CP) of CMV unless the C-terminal 42 amino acids were deleted from the PSV MP. As a result of the inoculation experiments, MP was considered the protein influencing symptom phenotypes on N. benthamiana and responsible for the host range difference on the pepper. Since plasmodesmata (PD) localization of viral MPs is essential for cell-to-cell movement, subcellular localization of GFP-tagged MPs (CMV-MP-eGFP, PSV-MP-eGFP) was observed. In the case of CMV-MP-eGFP, clear colocalization with PD was detected in both hosts, but PSV-MP-eGFP was not tightly connected to the PD in N. benthamiana and barely localized to the PD in C. annuum epidermal cells. Measuring Pearson correlation coefficients (PCCs) also supported the visual observation.