Ken-Taro Sekine

Enhanced Resistance to Cucumber mosaic virus in the Arabidopsis thaliana ssi2 Mutant Is Mediated via an SA-Independent Mechanism

The Arabidopsis thaliana SSI2 gene encodes a plastid-localized stearoyl-ACP desaturase. The recessive ssi2 mutant allele confers constitutive accumulation of the pathogenesis-related-1 (PR-1) gene transcript and salicylic acid (SA), and enhanced resistance to bacterial and oomycete pathogens. In addition, the ssi2 mutant is a dwarf and spontaneously develops lesions containing dead cells. Here, we show that the ssi2 mutant also confers enhanced resistance to Cucumber mosaic virus (CMV). Compared with the wild-type plant, viral multiplication and systemic spread were diminished in the ssi2 mutant plant. However, unlike the ssi2-conferred resistance to bacterial and oomycete pathogens, the ssi2-conferred enhanced resistance to CMV was retained in the SA-deficient ssi2 nahG plant. In addition, SA application was not effective in limiting CMV multiplication and systemic spread in the CMV-susceptible wild-type plant. The acd1, acd2, and cpr5 mutants which, like the ssi2 mutant, accumulate elevated SA levels, constitutively express the PR-1 gene, spontaneously develop lesions containing dead cells, and are dwarfs, are, however, fully susceptible to CMV. Our results suggest that dwarfing, cell death, and constitutive activation of SA signaling are not important for the ssi2-conferred enhanced resistance to CMV. However, the sfd1 and sfd4 mutations, which affect lipid metabolism, suppress the ssi2-conferred enhanced resistance to CMV, thus implicating a lipid or lipids in the ssi2-conferred resistance to CMV. Interestingly, the ssi2-conferred resistance to CMV was compromised in the ssi2 eds5 plant, suggesting the involvement of an SA-independent, EDS5-dependent mechanism in the ssi2-conferred resistance to CMV.

Overexpression of the Arabidopsis thaliana EDS5 gene enhances resistance to viruses

The Arabidopsis thaliana ENHANCED DISEASE SUSCEPTIBILITY 5 gene (EDS5) is required for salicylic acid (SA) synthesis in pathogen-challenged plants. SA and EDS5 have an important role in the Arabidopsis RCY1 gene-conferred resistance against the yellow strain of Cucumber mosaic virus [CMV(Y)], a Bromoviridae, and HRT-conferred resistance against the Tombusviridae, Turnip crinkle virus (TCV). EDS5 expression and SA accumulation are induced in response to CMV(Y) inoculation in the RCY1-bearing ecotype C24. To further discern the involvement of EDS5 in Arabidopsis defence against viruses, we overexpressed the EDS5 transcript from the constitutively expressed Cauliflower mosaic virus 35S gene promoter in ecotype C24. In comparison to the non-transgenic control, the basal level of salicylic acid (SA) was twofold higher in the 35S:EDS5 plant. Furthermore, viral spread and the size of the hypersensitive response associated necrotic local lesions (NLL) were more highly restricted in CMV(Y)-inoculated 35S:EDS5 than in the non-transgenic plant. The heightened restriction of CMV(Y) spread was paralleled by more rapid induction of the pathogenesis-related gene, PR-1, in the CMV(Y)-inoculated 35S:EDS5 plant. The 35S:EDS5 plant also had heightened resistance to the virulent CMV strain, CMV(B2), and TCV. These results suggest that, in addition to R gene-mediated gene-for-gene resistance, EDS5 is also important for basal resistance to viruses. However, while expression of the Pseudomonas putida nahG gene, which encodes the SA-degrading salicylate hydroxylase, completely suppressed 35S:EDS5-conferred resistance against CMV(Y) and TCV, it only partially compromised resistance against CMV(B2), indicating that SA-dependent and -independent mechanisms are associated with 35S:EDS5-conferred resistance against viruses.

Single amino acid alterations in Arabidopsis thaliana RCY1 compromise resistance to Cucumber mosaic virus, but differentially suppress hypersensitive response-like cell death.

Resistance to an yellow strain of Cucumber mosaic virus [CMV(Y)] in Arabidopsis thaliana ecotype C24 is conferred by the CC-NBS-LRR type R gene, RCY1. RCY1-conferred resistance is accompanied by a hypersensitive response (HR), which is characterized by the development of necrotic local lesion (NLL) at the site of infection that restricts viral spread. To further characterize the role of RCY1 in NLL formation we have identified six recessive CMV(Y)-susceptible rcy1 mutants, four of which contain single amino acid substitutions in RCY1: rcy1-2 contains a D to N substitution in the CC domain, rcy1-3 and rcy1-4 contain R to K and E to K substitutions, respectively, in the LRR domain, and rcy1-6 contains a W to C substitution in the NBS domain. The rcy1-5 and rcy1-7 contain nonsense mutations in the LRR and NBS domains, respectively. Although the virus systemically spread in all six rcy1 mutants, HR-associated cell death was differentially induced in these mutants. In comparison to the wild type C24 plant, HR was not observed in the CMV(Y)-inoculated leaves of the rcy1-3, rcy1-5, rcy1-6 and rcy1-7 mutants. In contrast, delayed NLL development was observed in the virus inoculated leaves of the rcy1-2 and rcy1-4 mutants. In addition, necrosis accompanied by elevated accumulation of PR gene transcript also appeared in the non-inoculated leaves of the rcy1-2 and rcy1-4 mutants. Trans-complementation was observed between the rcy1-2 and rcy1-4 alleles; in F1 plants derived from a cross between rcy1-2 and rcy1−4, HR associated cell death was accelerated and systemic spread of the virus was partially suppressed than in the homozygous rcy1-2 and rcy1-4 plants. Our results suggest that the CC, NBS and LRR domains of RCY1 are required for restriction of virus spread but differentially impact the induction of HR-like cell death. Furthermore, these results also predict inter-molecular interaction involving RCY1 in Arabidopsis resistance to CMV(Y).

Establishment of an agroinoculation system for broad bean wilt virus 2

We determined the complete nucleotide sequence of a broad bean wilt virus 2 (BBWV-2) isolate from gentian in Japan. The full-length RNA1 and RNA2 sequences, excluding poly(A) tails, were 5955 and 3600 nucleotides long, respectively. Analysis indicated that, in contrast to other BBWV-2 isolates, the 5’ end of both RNA1 and RNA2 starts with a GUU sequence. We successfully inoculated Nicotiana benthamiana with BBWV-2 by infiltrating a mixed suspension of two Agrobacterium tumefaciens clones carrying binary vectors with the full-length RNA1 and RNA2 sequences. This is the first report on the efficient, easy and high-throughput use of agroinoculation for generating BBWV-2 infections.

The Chloroplastic Protein THF1 Interacts with the Coiled-Coil Domain of the Disease Resistance Protein N′ and Regulates Light-Dependent Cell Death

A chloroplastic protein inhibits defense-induced cell death and is destabilized by activation of a disease resistance protein. One branch of plant immunity is mediated through nucleotide-binding/Leu-rich repeat (NB-LRR) family proteins that recognize specific effectors encoded by pathogens. Members of the I2-like family constitute a well-conserved subgroup of NB-LRRs from Solanaceae possessing a coiled-coil (CC) domain at their N termini. We show here that the CC domains of several I2-like proteins are able to induce a hypersensitive response (HR), a form of programmed cell death associated with disease resistance. Using yeast two-hybrid screens, we identified the chloroplastic protein Thylakoid Formation1 (THF1) as an interacting partner for several I2-like CC domains. Co-immunoprecipitations and bimolecular fluorescence complementation assays confirmed that THF1 and I2-like CC domains interact in planta and that these interactions take place in the cytosol. Several HR-inducing I2-like CC domains have a negative effect on the accumulation of THF1, suggesting that the latter is destabilized by active CC domains. To confirm this model, we investigated N′, which recognizes the coat protein of most Tobamoviruses, as a prototypical member of the I2-like family. Transient expression and gene silencing data indicated that THF1 functions as a negative regulator of cell death and that activation of full-length N′ results in the destabilization of THF1. Consistent with the known function of THF1 in maintaining chloroplast homeostasis, we show that the HR induced by N′ is light-dependent. Together, our results define, to our knowledge, novel molecular mechanisms linking light and chloroplasts to the induction of cell death by a subgroup of NB-LRR proteins.

Breakdown of plant virus resistance: can we predict and extend the durability of virus resistance?

Cultivars with introgressed natural resistance genes have been widely used for plant disease control, especially in the control of virus diseases, for which no effective chemical control agent is available. However, we often encounter virus mutants that break down or overcome the resistance. In this review, recent studies will be discussed with respect to breakdown of plant virus resistance.

Amino acids in Tobamovirus coat protein controlling pepper L1a gene-mediated resistance

In pepper plants (genus Capsicum), the resistance against Tobamovirus spp. is conferred by L gene alleles. The recently identified L variant L(1a) can recognize coat proteins (CPs) of Tobacco mild green mosaic virus Japanese strain (TMGMV-J) and Paprika mild mottle virus Japanese strain (PaMMV-J), but not of Pepper mild mottle virus (PMMoV), as the elicitor to induce resistance at 24 °C. Interestingly, L(1a) gene-mediated resistance against TMGMV-J, but not PaMMV-J, is retained at 30 °C. This observation led us to speculate that L(1a) can discriminate between CPs of TMGMV-J and PaMMV-J. In this study, we aimed to determine the region(s) in CP by which L(1a) distinguishes TMGMV-J from PaMMV-J. By using chimeric CPs consisting of TMGMV-J and PaMMV-J, we found that the chimeric TMGMV-J CP, whose residues in the β-sheet domain were replaced by those of PaMMV-J, lost its ability to induce L(1a) gene-mediated resistance at 30 °C. In contrast, the chimeric PaMMV-J CP with the β-sheet domain replaced by TMGMV-J CP was able to induce L(1a) gene-mediated resistance at 30 °C. Furthermore, viral particles were not detected in the leaves inoculated with either chimeric virus. These observations indicated that the amino acids within the β-sheet domain were involved in both the induction of L(1a) gene-mediated resistance and virion formation. Further analyses using chimeric CPs of TMGMV-J and PMMoV indicated that amino acids within the β-sheet domain alone were not sufficient for the induction of L(1a) gene-mediated resistance by TMGMV-J CP. These results suggest that multiple regions in Tobamovirus CP are implicated in the induction of L(1a) gene-mediated resistance.

Combined DECS Analysis and Next-Generation Sequencing Enable Efficient Detection of Novel Plant RNA Viruses

The presence of high molecular weight double-stranded RNA (dsRNA) within plant cells is an indicator of infection with RNA viruses as these possess genomic or replicative dsRNA. DECS (dsRNA isolation, exhaustive amplification, cloning, and sequencing) analysis has been shown to be capable of detecting unknown viruses. We postulated that a combination of DECS analysis and next-generation sequencing (NGS) would improve detection efficiency and usability of the technique. Here, we describe a model case in which we efficiently detected the presumed genome sequence of Blueberry shoestring virus (BSSV), a member of the genus Sobemovirus, which has not so far been reported. dsRNAs were isolated from BSSV-infected blueberry plants using the dsRNA-binding protein, reverse-transcribed, amplified, and sequenced using NGS. A contig of 4,020 nucleotides (nt) that shared similarities with sequences from other Sobemovirus species was obtained as a candidate of the BSSV genomic sequence. Reverse transcription (RT)-PCR primer sets based on sequences from this contig enabled the detection of BSSV in all BSSV-infected plants tested but not in healthy controls. A recombinant protein encoded by the putative coat protein gene was bound by the BSSV-antibody, indicating that the candidate sequence was that of BSSV itself. Our results suggest that a combination of DECS analysis and NGS, designated here as “DECS-C,” is a powerful method for detecting novel plant viruses.

Prevalence and genetic diversity of an unusual virus associated with Kobu-sho disease of gentian in Japan.

Gentian Kobu-sho-associated virus (GKaV) is a recently discovered novel virus from Kobu-sho (a hyperplastic or tumorous disorder)-affected Japanese gentians. To obtain insight into GKaV transmission and pathogenesis, the genetic diversity of the virus in the putative helicase and RNA-dependent RNA polymerase coding regions was studied. The extent of GKaV sequence diversity within single host plants differed within samples and between viral genomic regions. Phylogenetic analysis of 30 Kobu-sho-affected samples from different production areas and host cultivars revealed that GKaV populations have diverged as they became prevalent in different geographical regions. The diversification of GKaV was shown to be driven by geographical isolation rather than host adaptation; however, no geographical patterns were found. Therefore, it was not feasible to trace the pathway of GKaV spread.

Cauliflower mosaic virus Tav protein induces leaf chlorosis in transgenic tobacco through a host response to virulence function of Tav

To study the precise mechanisms underlying the chlorosis caused by plant viruses, we previously established a synchronous experimental system using transgenic plants expressing Cauliflower mosaic virus multifunctional protein, Tav (transactivator/viroplasmin), under the control of an artificially inducible promoter. Shortly after the induction of Tav expression, pathogenesis-related protein (PR) 1a gene expression is upregulated in the transgenic tobacco lines, which show visible chlorosis within a week. The present study showed that the expression of Tav also induces some salicylic acid (SA)- and ethylene-responsive PR genes. In contrast to transiently expressed Tav, which suppressed Agrobacterium-induced and SA-induced PR1a expression, the artificial induction of Tav from the transgene did not affect SA-induced PR1a expression, rather it alone induced PR1a expression. In a deletion analysis, chlorosis and PR1a induction function in transgenic tobacco were mapped to a region in Tav that had been shown to have a role in pathogenesis in a susceptible host, elicitation of the hypersensitive response in a resistant host, suppression of RNA silencing, and the suppression of Tomato bushy stunt virus P19-mediated cell death in tobacco. The results suggest that Tav-induced chlorosis results from a host response, which accompanies PR1a induction, to pathogenic function of Tav.