Yuko Ohashi

An improved assay for β-glucuronidase in transformed cells : methanol almost completely suppresses a putative endogenous β-glucuronidase activity

Abstract The bacterial β-glucuronidase (GUS) gene is often introduced into plants as a reporter gene fused to a promoter because of advantages over other reporter genes. However, many plants have non-neglegible levels of endogenous GUS or GUS-like activity which can interfere with the activity originating from the introduced GUS gene, especially if this level is a low one. To eliminate the endogenous GUS activity, we studied the effect of some water-soluble organic solvents on decreasing it and found that addition of methanol at 20% volume to a GUS reaction mixture was very effective, lowering the endogenous activity to 0–15% of the origin in all plant extracts tested. Moreover, methanol at this concentration enhanced by 1.4-fold the activity originating from the introduced GUS gene or GUS purified from E. coli. This method enabled us to determine GUS gene expression more reliably, after introduction of GUS gene fusion into rice protoplasts. In histochemical GUS analysis of transgenic tobacco, this method was also effective for suppressing the endogenous GUS activity.

Jasmonate-Based Wound Signal Transduction Requires Activation of WIPK, a Tobacco Mitogen-Activated Protein Kinase

A gene encoding a tobacco mitogen-activated protein kinase (WIPK) is transcriptionally activated in response to wounding. Transgenic tobacco plants, in which expression of endogenous wipk was suppressed, did not accumulate jasmonic acid or its methyl ester when wounded, suggesting that WIPK is involved in jasmonate-mediated wound signal transduction. Here, we demonstrate that activation of WIPK is required for triggering the jasmonate-mediated signal transduction cascade that occurs when wild-type tobacco plants are wounded. We also show that when plants are wounded, WIPK is rapidly and transiently activated, whereas the quantity of WIPK protein is maintained at a constant level. A transgenic tobacco plant in which the wipk gene was constitutively expressed at a high level showed constitutive enzymatic activation of WIPK and exhibited three- to fourfold higher levels of jasmonate than did its wild-type counterpart. This plant also showed constitutive accumulation of jasmonate-inducible proteinase inhibitor II transcripts. These results show that WIPK is activated in response to wounding, which subsequently causes an increase in jasmonate synthesis.

PCF1 and PCF2 Specifically Bind to cis Elements in the Rice Proliferating Cell Nuclear Antigen Gene

We have previously defined the promoter elements, sites IIa and IIb, in the rice proliferating cell nuclear antigen (PCNA) gene that are essential for meristematic tissue-specific expression. In this study, we isolated and characterized cDNAs encoding proteins that specifically bind to sites IIa and IIb. The two DNA binding proteins, designated PCF1 and PCF2, share > 70% homology in common conserved sequences at the N-terminal regions. The conserved regions are responsible for DNA binding and homodimer and heterodimer formation, and they contain a putative basic helix-loop-helix (bHLH) motif. The structure and DNA binding specificity of the bHLH motif are distinguishable from those of other known bHLH proteins that bind to the E-box. The motif is > 70% homologous to several expressed sequence tags from Arabidopsis and rice, suggesting that PCF1 and PCF2 are members of a novel family of proteins that are conserved in monocotyledons and dicotyledons. A supershift assay using an anti-PCF2 antibody showed the involvement of PCF2 in site IIa (site IIb) binding activities in rice nuclear extracts, particularly in meristematic tissues. PCF1 and PCF2 were also more likely to form heterodimers than homodimers. Our results suggest that PCF1 and PCF2 are involved in meristematic tissue-specific expression of the rice PCNA gene through binding to sites IIa and IIb and formation of homodimers or heterodimers.

Animal cell-death suppressors Bcl-xL and Ced-9 inhibit cell death in tobacco plants

In plants, events similar to programmed cell death have been reported [1] [2], although little is known of their mechanisms at the molecular level. To investigate the mechanism(s) involved, we overexpressed bcl-x(L), which encodes a mammalian suppressor of programmed cell death, in tobacco plants, under the control of a strong promoter [3]. In plants expressing Bcl-x(L), cell death induced by UV-B irradiation, paraquat treatment or the hypersensitive reaction (HR) to tobacco mosaic virus (TMV) infection was suppressed. The extent of suppression of cell death depended on the amount of Bcl-x(L) protein expressed. Similar enhanced resistance to cell death was found in transgenic tobacco plants overexpressing the ced-9 gene, a Caenorhabditis elegans homolog of bcl-x(L) [4], indicating that Bcl-x(L) and Ced-9 can function to inhibit cell death in plants.

Reduced Levels of Chloroplast FtsH Protein in Tobacco Mosaic Virus–Infected Tobacco Leaves Accelerate the Hypersensitive Reaction

In tobacco cultivars resistant to tobacco mosaic virus (TMV), infection results in the death of the infected cells accompanying the formation of necrotic lesions. To identify the genes involved in this hypersensitive reaction, we isolated the cDNA of tobacco DS9, the transcript of which decreases before the appearance of necrotic lesions. The DS9 gene encodes a chloroplastic homolog of bacterial FtsH protein, which serves to maintain quality control of some cytoplasmic and membrane proteins. A large quantity of DS9 protein was found in healthy leaves, whereas the quantity of DS9 protein in infected leaves decreased before the lesions appeared. In transgenic tobacco plants containing less and more DS9 protein than wild-type plants, the necrotic lesions induced by TMV were smaller and larger, respectively, than those on wild-type plants. These results suggest that a decrease in the level of DS9 protein in TMV-infected cells, resulting in a subsequent loss of function of the chloroplasts, accelerates the hypersensitive reaction.

Characteristic expression of twelve rice PR1 family genes in response to pathogen infection, wounding, and defense-related signal compounds (121/180)

Pathogenesis-related (PR) proteins have been used as markers of plant defense responses, and are classified into 17 families. However, precise information on the majority members in specific PR families is still limited. We were interested in the individual characteristics of rice PR1 family genes, and selected 12 putatively active genes using rice genome databases for expressed genes. All were upregulated upon compatible and/or incompatible rice-blast fungus interactions; three were upregulated in the early infection period and four in the late infection period. Upon compatible rice–bacterial blight interaction, four genes were upregulated, six were not affected, and one was downregulated. These results are in striking contrast to those among 22 ArabidopsisPR1 genes where only one gene was pathogen-inducible. The responses of individual genes to salicylic acid, jasmonic acid, and ethylene induced defense signaling pathways in rice are likely to be different from those in dicot plants. Transcript levels in healthy leaves, roots, and flowers varied according to each gene. Analysis of the partially overlapping expression patterns of rice PR1 genes in healthy tissues and in response to pathogens and other stresses would be useful to understand their possible functions and for use as characteristic markers for defense-related studies in rice.

Contribution of Ethylene Biosynthesis for Resistance to Blast Fungus Infection in Young Rice Plants

The role of ethylene (ET) in resistance to infection with blast fungus (Magnaporthe grisea) in rice (Oryza sativa) is poorly understood. To study it, we quantified ET levels after inoculation, using young rice plants at the four-leaf stage of rice cv Nipponbare (wild type) and its isogenic plant (IL7), which contains the Pi-i resistance gene to blast fungus race 003. Small necrotic lesions by hypersensitive reaction (HR) were formed at 42 to 72 h postinoculation (hpi) in resistant IL7 leaves, and whitish expanding lesions at 96 hpi in susceptible wild-type leaves. Notable was the enhanced ET emission at 48 hpi accompanied by increased 1-aminocyclopropane-1-carboxylic acid (ACC) levels and highly elevated ACC oxidase (ACO) activity in IL7 leaves, whereas only an enhanced ACC increase at 96 hpi in wild-type leaves. Among six ACC synthase (ACS) and seven ACO genes found in the rice genome, OsACS2 was transiently expressed at 48 hpi in IL7 and at 96 hpi in wild type, and OsACO7 was expressed at 48 hpi in IL7. Treatment with an inhibitor for ACS, aminooxyacetic acid, suppressed enhanced ET emission at 48 hpi in IL7, resulting in expanding lesions instead of HR lesions. Exogenously supplied ACC compromised the aminooxyacetic acid-induced breakdown of resistance in IL7, and treatment with 1-methylcyclopropene and silver thiosulfate, inhibitors of ET action, did not suppress resistance. These findings suggest the importance of ET biosynthesis and, consequently, the coproduct, cyanide, for HR-accompanied resistance to blast fungus in young rice plants and the contribution of induced OsACS2 and OsACO7 gene expression to it.

Phytoalexin Accumulation in the Interaction Between Rice and the Blast Fungus

Blast fungus-induced accumulations of major rice diterpene phytoalexins (PA), momilactones A and B, and phytocassanes A through E were studied, focusing on their biosynthesis and detoxification. In resistant rice, all PA started to accumulate at 2 days postinoculation (dpi), at which hypersensitive reaction (HR)-specific small lesions became visible and increased 500- to 1,000-fold at 4 dpi, while the accumulation was delayed and several times lower in susceptible rice. Expression of PA biosynthetic genes was transiently induced at 2 dpi only in resistant plants, while it was highly induced in both plants at 4 dpi. Fungal growth was severely suppressed in resistant plants by 2 dpi but considerably increased at 3 to 4 dpi in susceptible plants. Momilactone A treatment suppressed fungal growth in planta and in vitro, and the fungus detoxified the PA in vitro. These results indicate that HR-associated rapid PA biosynthesis induces severe restriction of fungus, allowing higher PA accumulation in resistant rice, while in susceptible rice, failure of PA accumulation at the early infection stage allows fungal growth. Detoxification of PA would be a tactic of fungus to invade the host plant, and prompt induction of PA biosynthesis upon HR would be a trait of resistant rice to restrict blast fungus.

Diverse expression profiles of 21 rice peroxidase genes

Secretory class III plant peroxidases (POXs) catalyze the oxidation of various reductants, and are encoded by a large multigene family. In rice, 42 independent expressed sequence tags for POXs have been identified. By RNA gel blot analysis using specific probes, we show here that 21 rice POX genes are unique in their developmental, organ specific and external stimuli‐responsive expression. This would suggest that encoded POX isoenzymes are involved in a broad range of physiological processes in rice plants, individually.

E2Ls, E2F-like Repressors of Arabidopsis That Bind to E2F Sites in a Monomeric Form

E2F transcription factors are major regulators of cell proliferation, and each factor contributes differently to cell cycle control. Arabidopsis contains six E2F homologs, of which three are proteins that exhibit an overall similarity to animal E2Fs and interact with DPa and DPb to stimulate DNA binding. Here we describe the other three E2F-like proteins fromArabidopsis, E2L1–3, which have two copies of a domain with a limited similarity only to the DNA binding domain of E2F. Unlike known E2Fs, the three E2L proteins failed to interact with DPa and DPb and could efficiently bind E2F sites in a monomeric form through the dual-type domain. Transfection assays revealed that E2Ls repress the transcription of reporter genes under the control of E2F-regulated promoters, indicating that E2Ls function to antagonize transactivation mediated by E2F·DP. When fused to green fluorescence protein, E2L1 and E2L3 were predominantly localized to the nucleus whereas E2L2 was detected in both the nucleus and cytoplasm. Because the transcripts of E2Ls were abundant in meristematic rather than fully differentiated tissues, E2Ls may balance the activities of E2F·DP and play a role in restraining cell proliferation.