Perilla Mosaic Virus Is a Highly Divergent Emaravirus Transmitted by Shevtchenkella sp. (Acari: Eriophyidae).

Shiso (Perilla frutescens var. crispa) is widely grown as an important vegetable or herb crop in Japan. Beginning around the year 2000, occurrences of severe mosaic symptoms on shiso were documented and gradually spread across Kochi Prefecture, one of four major shiso production areas in Japan. Next generation sequencing and cloning indicated the presence of a previously unknown virus related to the members of the genus Emaravirus, for which we proposed the name Perilla mosaic virus (PerMV). The genome of PerMV consists of 10 RNA segments, each encoding a single protein in the negative-sense orientation. Of these proteins, P1, P2, P3a, P3b, P4, and P5 show amino acid sequence similarities with those of known emaraviruses, whereas no similarities were found in P6a, P6b, P6c, and P7. Characteristics of the RNA segments as well as phylogenetic analysis of P1 to P4 indicate that PerMV is a distinct and highly divergent emaravirus. Electron microscopy observations and protein analyses corresponded to presence of an emaravirus. Transmission experiments demonstrated that an eriophyid mite, Shevtchenkella sp. (family Eriophyidae), transmits PerMV with a minimum 30-min acquisition access period. Only plants belonging to the genus Perilla tested positive for PerMV, and the plant-virus-vector interactions were evaluated. The nucleotide sequences reported here are available in the DDBJ/ENA/GenBank databases under accession numbers LC496090 to LC496099.

Functional differentiation in the leucine-rich repeat domains of closely related plant virus-resistance proteins that recognize common avr proteins.

The N' gene of Nicotiana sylvestris and L genes of Capsicum plants confer the resistance response accompanying the hypersensitive response (HR) elicited by tobamovirus coat proteins (CP) but with different viral specificities. Here, we report the identification of the N' gene. We amplified and cloned an N' candidate using polymerase chain reaction primers designed from L gene sequences. The N' candidate gene was a single 4143 base pairs fragment encoding a coiled-coil nucleotide-binding leucine-rich repeat (LRR)-type resistance protein of 1,380 amino acids. The candidate gene induced the HR in response to the coexpression of tobamovirus CP with the identical specificity as reported for N'. Analysis of N'-containing and tobamovirus-susceptible N. tabacum accessions supported the hypothesis that the candidate is the N' gene itself. Chimera analysis between N' and L(3) revealed that their LRR domains determine the spectrum of their tobamovirus CP recognition. Deletion and mutation analyses of N' and L(3) revealed that the conserved sequences in their C-terminal regions have important roles but contribute differentially to the recognition of common avirulence proteins. The results collectively suggest that Nicotiana N' and Capsicum L genes, which most likely evolved from a common ancestor, differentiated in their recognition specificity through changes in the structural requirements for LRR function.

Single amino acid substitution in the methyltransferase domain of Paprika mild mottle virus replicase proteins confers the ability to overcome the high temperature-dependent Hk gene-mediated resistance in Capsicum plants.

Capsicum plants harboring the Hk gene (Hk) show resistance to Paprika mild mottle virus (PaMMV) at 32 degrees C but not 24 degrees C. To identify the viral elicitor that activates the Hk-mediated resistance, several chimeric viral genomes were constructed between PaMMV and Tobacco mosaic virus-L. Infection patterns of these chimeric viruses in Hk-harboring plants revealed responsibility of PaMMV replicase genes for activation of the Hk-mediated resistance. The comparison of nucleotide sequence of replicase genes between PaMMV and PaHk1, an Hk-resistance-breaking strain of PaMMV, revealed that the adenine-to-uracil substitution at the nucleotide position 721 causes an amino acid change from threonine to serine at the 241st residue in the methyltransferase domain. Introduction of the A721U mutation into the replicase genes of parental PaMMV overcame the Hk resistance at 32 degrees C. The results indicate that Hk-mediated resistance is induced by PaMMV replicase proteins and that methyltransferase domain has a role in this elicitation.

The coat protein gene of tobamovirus P 0 pathotype is a determinant for activation of temperature-insensitive L 1a-gene-mediated resistance in Capsicum plants.

Tobamovirus resistance in Capsicum plants, which is mediated by L genes (L(1), L(2), L(3) or L(4)), is known to be temperature sensitive. However, the L(1a ) gene, a newly identified tobamovirus resistance gene that is mapped to the L locus, confers temperature-insensitive resistance against the tobamovirus P(0) pathotype. To identify the viral elicitor that activates the L(1a )-gene-mediated resistance, several chimeric viral genomes were constructed between tobacco mosaic virus-L (P(0) pathotype), paprika mild mottle virus-J (P(1 )pathotype) and pepper mild mottle virus-J (P(1,2) pathotype). Infection patterns of these chimeric viruses in L(1a )-harboring plants revealed that the L(1a )-gene-mediated resistance was activated by the CP of a particular pathotype of tobamovirus, like other L-gene-mediated resistances, but the L(1a )-gene-mediated resistance differs from those conferred by other L genes in terms of temperature sensitivity.

Cooperative effect of two amino acid mutations in the coat protein of Pepper mild mottle virus overcomes L3-mediated resistance in Capsicum plants.

We found that an L3 resistance-breaking field isolate of Pepper mild mottle virus (PMMoV), designated PMMoV-Is, had two amino acid changes in its coat protein (CP), namely leucine to phenylalanine at position 13 (L13F) and glycine to valine at position 66 (G66V), as compared with PMMoV-J, which induces a resistance response in L3-harboring Capsicum plants. The mutations were located to a CP domain corresponding to the outer surface of PMMoV particles in computational molecular modeling. Analyses of PMMoV CP mutants containing either or both of these amino acid changes revealed that both changes were required to efficiently overcome L3-mediated resistance with systemic necrosis induction. Although CP mutants containing either L13F or G66V could not efficiently overcome L3-mediated resistance, these amino acid changes had different effects on the elicitor activity of PMMoV CP. L13F caused a slight reduction in the elicitor activity, resulting in virus restriction to necrotic local lesions that were apparently larger than those induced by wild-type PMMoV, while G66V rendered wild-type PMMoV the ability to overcome L3-mediated resistance, albeit with a lower efficiency than PMMoV with both changes. These results suggest that a cooperative effect of the L13F and G66V mutations on the elicitor activity of CP is responsible for overcoming the L3-mediated resistance.