An antifungal compound involved in symbiotic germination of Cypripedium macranthos var. rebunense (Orchidaceae)

Germination of orchid seeds fully depends on a symbiotic association with soil-borne fungi, usually Rhizoctonia spp. In contrast to the peaceful symbiotic associations between many other terrestrial plants and mycorrhizal fungi, this association is a life-and-death struggle. The fungi always try to invade the cytoplasm of orchid cells to obtain nutritional compounds. On the other hand, the orchid cells restrict the growth of the infecting hyphae and obtain nutrition by digesting them. It is likely that antifungal compounds are involved in the restriction of fungal growth. Two antifungal compounds, lusianthrin and chrysin, were isolated from the seedlings of Cypripedium macranthos var. rebunense that had developed shoots. The former had a slightly stronger antifungal activity than the latter, and the antifungal spectra of these compounds were relatively specific to the nonpathogenic Rhizoctonia spp. The level of lusianthrin, which was very low in aseptic protocorm-like bodies, dramatically increased following infection with the symbiotic fungus. In contrast, chrysin was not detected in infected protocorm-like bodies. These results suggest that orchid plants equip multiple antifungal compounds and use them at specific developmental stages; lusianthrin maintains the perilous symbiotic association for germination and chrysin helps to protect adult plants

A novel virus-like double-stranded RNA in an obligate biotroph arbuscular mycorrhizal fungus: a hidden player in mycorrhizal symbiosis

Arbuscular mycorrhizal (AM) fungi form mutualistic associations with most land plants and enhance phosphorus uptake of the host plants. Fungal viruses (mycoviruses) that possess a double-stranded RNA (dsRNA) genome often impact on plant-fungal interactions via altering phenotypic expression of their host fungi. The present study for the first time demonstrates the presence of dsRNAs, which is highly likely to be mycoviruses, in AM fungi. dsRNA was extracted from mycelia of Glomus sp. RF1, purified, and subjected to electrophoresis. The fungus was found to harbor various dsRNA segments that differed in size. Among them, a 4.5-kbp segment was termed Glomus sp. RF1 virus-like-medium dsRNA (GRF1V-M) and characterized in detail. The GRF1V-M genome segment was 4,557 nucleotides in length and encoded RNA-dependent RNA polymerase and a structural protein. GRF1V-M was phylogenetically distinct and could not be assigned to known genera of mycovirus. The GRF1V-M-free culture line of Glomus sp. RF1, which was raised by single spore isolation, produced two-fold greater number of spores and promoted plant growth more efficiently than the GRF1V-M-positive lines. These observations suggest that mycoviruses in AM fungi, at least some of them, have evolved under unique selection pressures and are a biologically active component in the symbiosis

A unique mitovirus from Glomeromycota, the phylum of arbuscular mycorrhizal fungi

Arbuscular mycorrhizal (AM) fungi that belong to the phylum Glomeromycota associate with most land plants and supply mineral nutrients to the host plants. One of the four viral segments found by deep-sequencing of dsRNA in the AM fungus Rhizophagus clarus strain RF1 showed similarity to mitoviruses and is characterized in this report. The genome segment is 2,895 nucleotides in length, and the largest ORF was predicted by applying either the mold mitochondrial or the universal genetic code. The ORF encodes a polypeptide of 820 amino acids with a molecular mass of 91.2 kDa and conserves the domain of the mitovirus RdRp superfamily. Accordingly, the dsRNA was designated as R. clarus mitovirus 1 strain RF1 (RcMV1-RF1). Mitoviruses are localized exclusively in mitochondria and thus generally employ the mold mitochondrial genetic code. The distinct codon usage of RcMV1-RF1, however, suggests that the virus is potentially able to replicate not only in mitochondria but also in the cytoplasm. RcMV1-RF1 RdRp showed the highest similarity to the putative RdRp of a mitovirus-like ssRNA found in another AM fungus, followed by RdRp of a mitovirus in an ascomycotan ectomycorrhizal fungus. The three mitoviruses found in the three mycorrhizal fungi formed a deeply branching clade that is distinct from the two major clades in the genus Mitovirus

Construction of a de novo assembly pipeline using multiple transcriptome data sets from Cypripedium macranthos (Orchidaceae)

The family Orchidaceae comprises the most species of any monocotyledonous family and has interesting characteristics such as seed germination induced by mycorrhizal fungi and flower morphology that co-adapted with pollinators. In orchid species, genomes have been decoded for only a few horticultural species, and there is little genetic information available. Generally, for species lacking sequenced genomes, gene sequences are predicted by de novo assembly of transcriptome data. Here, we devised a de novo assembly pipeline for transcriptome data from the wild orchid Cypripedium (lady slipper orchid) in Japan by mixing multiple data sets and integrating assemblies to create a more complete and less redundant contig set. Among the assemblies generated by combining various assemblers, Trinity and IDBA-Tran yielded good assembly with higher mapping rates and percentages of BLAST hit contigs and complete BUSCO. Using this contig set as a reference, we analyzed differential gene expression between protocorms grown aseptically or with mycorrhizal fungi to detect gene expressions required for mycorrhizal interaction. A pipeline proposed in this study can construct a highly reliable contig set with little redundancy even when multiple transcriptome data are mixed, and can provide a reference that is adaptable to DEG analysis and other downstream analysis in RNA-seq

The 2b proteins of Cucumber mosaic virus generally have the potential to differentially induce necrosis on Arabidopsis

Plant viral symptoms are rarely explained by direct molecular interaction between a viral protein and a host factor, but rather understood as a consequence of arms race between host RNA silencing and viral silencing suppressors. However, we have recently demonstrated that the 2b protein (2b) of Cucumber mosaic virus (CMV) HL strain could bind to Arabidopsis catalase that is important in scavenging cellular hydrogen peroxide, leading to the induction of distinct necrosis on Arabidopsis. Because we previously used virulent strains of subgroup I CMV in the study, we here further analyzed mild strains of subgroup II CMV, which share 70 to 80% sequence homology with subgroup I, to understand whether the necrosis induction is a general phenomenon to compromise host defense system mediated by catalase in the pathosystem of any CMV strains and Arabidopsis. Based on the results, we concluded that 2bs of subgroup II could also bind to catalase, resulting in decrease in catalase activity and weak necrosis on Arabidopsis. Because the 2b-catalase interaction did not prevent CMVs from spreading, it may eventually operate in favor of CMV

Allexiviruses may have acquired inserted sequences between the CPand CRP genes to change the translation reinitiation strategy of CRP

AbstractAllexiviruses are economically important garlic viruses that are involved in garlic mosaic diseases. In this study, we characterizedthe allexivirus cysteine-rich protein (CRP) gene located just downstream of the coat protein (CP) gene in the viralgenome. We determined the nucleotide sequences of the CP and CRP genes from numerous allexivirus isolates and performeda phylogenetic analysis. According to the resulting phylogenetic tree, we found that allexiviruses were clearly divided intotwo major groups (group I and group II) based on the sequences of the CP and CRP genes. In addition, the allexiviruses ingroup II had distinct sequences just before the CRP gene, while group I isolates did not. The inserted sequence between theCP and CRP genes was partially complementary to garlic 18S rRNA. Using a potato virus X vector, we showed that theCRPs affected viral accumulation and symptom induction in Nicotiana benthamiana, suggesting that the allexivirus CRP isa pathogenicity determinant. We assume that the inserted sequences before the CRP gene may have been generated duringviral evolution to alter the termination-reinitiation mechanism for coupled translation of CP and CRP

N-¹, N-¹⁴-diferuloylspermine as an antioxidative phytochemical contained in leaves of Cardamine fauriei

Most Brassicaceae vegetables are ideal dietary sources of antioxidants beneficial for human health. Cardamine fauriei (Ezo-wasabi in Japanese) is a wild, edible Brassicaceae herb native to Hokkaido, Japan. To clarify the main antioxidative phytochemical, an 80% methanol extraction from the leaves was fractionated with Diaion (R) HP-20, Sephadex (R) LH-20, and Sep-Pak (R) C18 cartridges, and the fraction with strong antioxidant activity depending on DPPH method was purified by HPLC. Based on the analyses using HRESIMS and MS/MS, the compound might be N-1, N-14-diferuloylspermine. This rare phenol compound was chemically synthesized, whose data on HPLC, MS and H-1 NMR were compared with those of naturally derived compound from C. fauriei. All results indicated they were the same compound. The radical-scavenging properties of diferuloylspermine were evaluated by ORAC and ESR spin trapping methods, with the diferuloylspermine showing high scavenging activities of the ROO, O-2(-), and HO radicals as was those of conventional antioxidants

Importin/exportin-mediated nucleocytoplasmic shuttling of cucumber mosaic virus 2b protein is required for 2b's efficient suppression of RNA silencing

Author summaryRNA silencing, a small RNA (sRNA)-mediated sequence-specific mechanism, is a primary antiviral response of host plants against viral infection. Argonaute 1 (AGO1), an effector protein of RNA silencing, associates with sRNAs to degrade viral RNAs or silence the genes involved in biotic stresses in cytoplasm; such functions are promoted by its translocation between the nucleus and cytoplasm. To survive host RNA silencing, cucumber mosaic virus (CMV) encodes an RNA silencing suppressor (RSS), 2b protein (2b). 2b plays multiple roles in suppressing RNA silencing by binding to either sRNAs or AGOs, in the nucleus and the cytoplasm. However, several previous reports suggest that 2b exerts its RSS activity mainly when it is in the cytoplasm. Here, we found that the serine residue at position 28 is phosphorylated, and its phosphorylation negatively regulated the RSS activity of 2b by regulating 2b's nuclear/nucleolar localization. Furthermore, we also found that 2bs were dephosphorylated in the nucleus and exported to the cytoplasm in an exportin-dependent manner. Because 2b's transport between the nucleus and cytoplasm is similar to that of AGOs, 2b seems to work in cells as if it is manipulating its nucleocytoplasmic trafficking to track down its targets in the RNA silencing pathway. The 2b protein (2b) of cucumber mosaic virus (CMV), an RNA-silencing suppressor (RSS), is a major pathogenicity determinant of CMV. 2b is localized in the nucleus and cytoplasm, and its nuclear import is determined by two nuclear localization signals (NLSs); a carrier protein (importin [IMP alpha]) is predicted to be involved in 2b's nuclear transport. Cytoplasmic 2bs play a role in suppression of RNA silencing by binding to small RNAs and AGO proteins. A putative nuclear export signal (NES) motif was also found in 2b, but has not been proved to function. Here, we identified a leucine-rich motif in 2b's C-terminal half as an NES. We then showed that NES-deficient 2b accumulated abundantly in the nucleus and lost its RSS activity, suggesting that 2b exported from the nucleus can play a role as an RSS. Although two serine residues (S40 and S42) were previously found to be phosphorylated, we also found that an additional phosphorylation site (S28) alone can affect 2b's nuclear localization and RSS activity. Alanine substitution at S28 impaired the IMP alpha-mediated nuclear/nucleolar localization of 2b, and RSS activity was even stronger compared to wild-type 2b. In a subcellular fractionation assay, phosphorylated 2bs were detected in the nucleus, and comparison of the accumulation levels of nuclear phospho-2b between wild-type 2b and the NES mutant showed a greatly reduced level of the phosphorylated NES mutant in the nucleus, suggesting that 2bs are dephosphorylated in the nucleus and may be translocated to the cytoplasm in a nonphosphorylated form. These results suggest that 2b manipulates its nucleocytoplasmic transport as if it tracks down its targets, small RNAs and AGOs, in the RNA silencing pathway. We infer that 2b's efficient RSS activity is maintained by a balance of phosphorylation and dephosphorylation, which are coupled to importin/exportin-mediated shuttling between the nucleus and cytoplasm

Evidence of capsaicin synthase activity of the Pun1-encoded protein and its role as a determinant of capsaicinoid accumulation in pepper

Background: Capsaicinoids, including capsaicin and its analogs, are responsible for the pungency of pepper (Capsicum species) fruits. Even though capsaicin is familiar and used daily by humans, the genes involved in the capsaicin biosynthesis pathway have not been well characterized. The putative aminotransferase (pAMT) and Pungent gene 1 (Pun1) proteins are believed to catalyze the second to last and the last steps in the pathway, respectively, making the Pun1 protein the putative capsaicin synthase. However, there is no direct evidence that Pun1 has capsaicin synthase activity. Results: To verify that the Pun1 protein actually plays a role in capsaicin production, we generated anti-Pun1 antibodies against an Escherichia coli-synthesized Pun1 protein and used them to antagonize endogenous Pun1 activity. To confirm the anti-Pun1 antibodies' specificity, we targeted Pun1 mRNA using virus-induced gene silencing. In the Pun1-down-regulated placental tissues, the accumulated levels of the Pun1 protein, which was identified on a western blot using the anti-Pun1 antibodies, were reduced, and simultaneously, capsaicin accumulations were reduced in the same tissues. In the de novo capsaicin synthesis in vitro cell-free assay, which uses protoplasts isolated from placental tissues, capsaicin synthesis was inhibited by the addition of anti-Pun1 antibodies. We next analyzed the expression profiles of pAMT and Pun1 in various pepper cultivars and found that high levels of capsaicin accumulation always accompanied high expression levels of both pAMT and Pun1, indicating that both genes are important for capsaicin synthesis. However, comparisons of the accumulated levels of vanillylamine (a precursor of capsaicin) and capsaicin between pungent and nonpungent cultivars revealed that vanillylamine levels in the pungent cultivars were very low, probably owing to its rapid conversion to capsaicin by Pun1 soon after synthesis, and that in nonpungent cultivars, vanillylamine accumulated to quite high levels owing to the lack of Pun1. Conclusions: Using a newly developed protoplast-based assay for de novo capsaicin synthesis and the anti-Pun1 antibodies, we successfully demonstrated that the Pun1 gene and its gene product are involved in capsaicin synthesis. The analysis of the vanillylamine accumulation relative to that of capsaicin indicated that Pun1 was the primary determinant of their accumulation levels